V. CATALOGUE OF GENE SYMBOLS FOR WHEAT: 1999 Supplement

R.A. McIntosh 1 , G.E. Hart 2 , K.M. Devos 3 and W.J. Rogers 4.

1 Plant Breeding Institute, The University of Sydney, 107 Cobbitty Rd., Cobbitty, N.S.W., Australia, 2570.
2 Department of Soil & Crop Sciences, Texas A&M University, College Station, Texas, USA, 77843.
3 John Innes Centre, Norwich Research Park, Colney, Norwich, Norfolk, NR4 7UH, UK.
4 Catedra de Genetica y Fitotecnia, Universidad Nacional del Centro de la Provincia de Buenos Aires, 7300 Azul,
Argentina.

The most recent edition of the Catalogue appeared in the Proceedings of the 9th International Wheat Genetics Symposium Vol. 5 (Slinkard AE ed., University Extension Press, University of Saskatchewan, Saskatoon, Canada). A modified version is displayed on the Graingenes Website: http://wheat.pw.usda.gov/ggpages/pubs.html.

The present Supplement has been offered to the editors of Annual Wheat Newsletter and Wheat Information Service for inclusion in the respective journals. Researchers and readers are encouraged to advise the curators of updatings and errors as this will make the Catalogue more useful to others.

Significant Revisions for the 1998 Catalogue.

Introduction
P1. Rule 6(ii) - change "homoeologous" to "orthologous" in both positions.

DNA Markers
P19. Immediately below the table insert: 'Markers are listed in alphabetical/numerical order within each group with the exception of markers whose symbol does not include a laboratory designation; these are listed at the beginning of each group.'
P23. Xcmwg701-1A.1,.2 should be moved one line below its present position.
P26. Xzens1(Adpg4)-1A. Add reference {757} to synonym XAga7 and add probe: 'WE:aga7 {774}.'.
P31. Xfba209. Delete second entry. Modify first entry to:
Xfba209-2A, B.1, .2 [{154}], 2D.1, .2 {1160}.
[Xfba209b-2A, Xfba209a-2B, Xfba209c-2B {154}]. FBA209. (5D).
P57. XksuF43. Delete second entry. Modify first entry to:
XksuF43-5D.1, .2 [{448}]. [XksuF43(A), (B)-5D {448}]. pTtksuF43. (1B,D, 2D, 4D, 6D).
P61. XksuE3. Should be listed after XksuD27.

1999 Supplement

Laboratory Designators for DNA markers

Add:

abg (Barley genomic* clones)

Kleinhofs, A. (see abc)

 

bg (Barley genomic* clones)

Lapitan, N.

Department of Soil and Crop Sciences

Colorado State University

Fort Collins, CO 80526

USA

 

cmwg (Barley cDNA* clones)

Graner, A. (see mwg)

cs Appels, R. (see csb)

 

fra Bernard, Michel
INRA
Station d'Amelioration des Plantes
234, Avenue du Brezet
63039 Clermont-Ferrand Cedex 2

France*

 

gbx Jacquemin, J.M.

Centre de Recherches Agronomiques

Station d'Amélioration des Plantes

4, rue du Bordia

B-5030 Gembloux*

Belgium

 

lars Holdsworth, M.J.

IACR - Long Ashton Research Station*

Department of Agricultural Sciences

University of Bristol

Long Ashton, Bristol BS18 9AF

UK

 

logt Volckaert, G.

Laboratory of Gene Technology*

Katholieke Universiteit Leuven

Willem de Croylaan 42

B-3001 Leuven

Belgium

 

ucw Dubcovsky, J.
Department of Agronomy and
Range Science
University of California*-Davis
One Shields Avenue
Davis, California 95616-8515
USA

 

uta Browning, Karen

Department of Chemistry

University of Texas*

Austin*, Texas

USA

 

whs Hartl, L.

Institute of Agronomy and Plant Breeding

Freising-Weihenstephan*

Germany

 

wsuj Jones*, S.S.

Department of Crop and Soil Sciences

Washington State University*

Pullman, WA 99164

USA


ycu Ogihara, Y.

Kihara Institute for Biological Research

Yokohama City University*

Maioka-cho 641-12

Yokahama 244

Japan

Morphological, Physiological, Molecular and DNA Traits

Gross Morphology: Spike characteristics

1. Squarehead/spelt

q. ma: Q 9.3 cM Xpsr370-5A {9903}.

4. Branched spike

bh. 2AS add: {9907}. Add: 'A chromosome 2B gene of minor effect was identified {9907} and an inhibitor was associated with chromosome 2D {9907}.'
'In a monosomic analysis of the hexaploid line LYB with supernumerary spikelets, Peng et al. {9908} located recessive genes in chromosomes 2A and 4A that promote the development of supernumerary spikelets and a gene in chromosome 2D that prevents their expression.'

5. Elongated glume

In the existing preamble change 'P' to 'P1 [P]' and add: 'A second gene is present in chromosome 7B {9990}.'
P1. [P {911}; Eg {922}].
P2 {9990}. 7BL{9990}. ti: LD222*7/T. ispahanicum {9990}.
tv: T. ispahanicum {9990}.

Anthocyanin Pigmentation

1. Purple anthers.

Add at end of section:
'Pan2. 7AS {9959}. tv: T. turgidum subsp. dicoccoides acc. MG4343 {9959}. ma: Pan2 9.2 cM Rc1 12.2 cM Xutv1267-7A (proximal) {9959}.'

3. Red/purple coleoptiles.

Rc1. Add at end of section: 'tv: T. turgidum subsp. dicoccoides acc. MG4343 {9959}. ma: Pan2 9.2 cM Rc1 12.2 cM Xutv1267-7A (proximal) {9959}.'

Brittle Rachis

Br1 {9970}. 3DS {9970}. A single dominant gene controlling brittle rachis in T. aestivum var. tibetanum was reported {9970}.

Dormancy (seed)

Phs. 7D {9960}. Semi-dominant {9960}. v: Soleil {9960}. ma: Weakly associated with Xpsp3003-7D {9960}.

DNA Markers

Group 1S

Amendments:

• Xcdo388-1B,D. Add '3D', '4D', and '6D' in the last column.
• Xcdo1188-1A,B,D. Change to 'Xcdo1188-1A.1 [{280}]3,5, 1B.1 [{1529}]1, 1D {445}1.' and add '(1AL,BL).' in the last column.
• Xglk558-1D. Remove {822}, add '1B,DL', '3D', '6D', and '7D' in the last column, and remove 'Note: The arm location of Xglk558-1D in T. tauschii was not reported in {822}.'.
• Xgwm30-1A. Add '3A' in the third column.
• Xgwm33-1A. Revise to 'Xgwm33-1A {1226}, 1B,D {9929}.'.
• XksuD14-1A.1. Change to 'XksuD14-1A.1,.2.'.

Group 1L

Amendments:

• Xabg387-1A.1,.2, 1B,D. Add '6A,B' in the last column.
• Xabg464-1A. Add '(2D).' in the last column.
• Xbcd454-1A. Add '(5A).' in last column.
• Xbg542-1D. Add '(3D).' in the last column.
• Xcdo393-1A {1529}1, {280}3, 1B {981050}. Change reference {981050} to '{154}1'.
• Xcdo1312-1B . Add '5D' in the last column.
• Xcmwg706-1A. Add ', 1D.1,.2 {9926}4' in the 1st column.'
• Xcmwg758-1A,B. Add '(1D).' in the 4th column.
• Xglk427-1B {822}. Add '(1D, 3D).' in the 4th column.
• Xglk558-1B,D. Delete ', 1D {822}' from the 1st column and add '1DS,D', '3D', '6D' and '7D' in the last column.
• Xgwm33-1B. Delete (moved to 1S).
• XksuG55-1D.1,.2. Add '(2D).' in the last column.
• XksuM114-1B,D. Add '(4D).' in the last column.
• XpsrX-1A,B,D {905}. Delete this entry (the clone that detected the locus is unknown).
• Xpsr946-1D. Add '6D' in the last column.

Amendments:

• Xcdo675-1D. Add '(2D, 7D).' in the last column.
• Xglk652-1D. Add '3D' in the last column.
• Xglk732-1A. Add '(2D).' in the last column.
• Xglk764-1B. Add '(7D).' in the last column.
• XksuD16-1D. Change last column to '(5A,B,D).'.
• Xwg908-1A. Change last column to '(5A,B,D).'.

Group 2S

Amendments:

• Xabg378-2A. Add '6A,D' in the last column.
• Xbcd1709-2B. Change to 'Xbcd1709-2A {9959}2, 2B {1060}1.'.
• Xcdo64-2A,B,D. Add '(3D, 4D).' in the last column.
• Xgwm129-2B. Add '(5A).' in the last column.
• Xgwm515-2D. Add '(2A)'. in the last column.
• XksuD18-2B. Add superscript '1' to '{154}'.
• XksuF11-2B. Add '2D' in the last column.
• XksuF19-2A,B,D. Add 'The arm location of XksuF19-2D in T. tauschii was not reported in {448}.'.
• Xpsr131-2A,B,D. Add '(5D).' in the last column.
• Xpsr933-2A,D. Change to 'Xpsr933-2A {256}1, 2B {9959}2, 2D {256}1.'.
• Xpsr946-2D. Add '1D' and '6D' in the last column.

Amendments:

• Xabc451-2A. Add '(6D).' in the last column.
• Xabg496-2A. Add '(5A).' in the last column.
• Xbcd410-2A,D. Add '(7D).' in the last column.
• Xbg123-2A. Add ', 2D {9926}4.' in the first column.
• Xcdo388-2B . Add superscript '1' to '{1060}' and ', 2D {9926}4' and add '3D', '4D', and '6D' in the last column.
• Xcmwg720-2A. Add ', 2D {9926}4' in the first column.
• Xgwm16-2B. Add '(5D, 7D).' in the last column.
• Xgwm30-2D. Add '3A' in the last column.
• Xgwm47-2B. Change to 'Xgwm47-2A.1,.2 [{9929}], 2B {1226,1225}.' and add '[Xgwm47.1-2A, Xgwm47.2-2A {9929}] .' in the second column.
• Xgwm55-2B. Change to 'Xgwm55-2B.1 [{1225}],{9929}.', add '[Xgwm55-2B {1225}].' in the second column, and add '(6D).' in the last column.
• Xgwm191-2B. Add '(5B, 6B).' in the last column.
• Xgwm382-2A,D. Change to 'Xgwm382-2A {1225}, 2B {9929}, 2D {1225}.'. Xgwm608-2D. Add '(4D).' in the last column.
• XksuF1-2A,B. In the last column, delete '2B,D' and change '5A' to '5A,B,D'. XksuF11-2A,B. Add '2D' in the last column.
• Xmwg546-2B . Change 1st column to 'Xmwg546-2B {1060}1, 2D {9926}4.'. Xpsr101(psk-1)-2A,B,D. Capitalize 'Psk'.
• Xwg184-2D. Add '3D' in the last column.
• Xwg645-2A,B,D. Add '(1D).' in the last column.
• Xwsu2(Pk)-2B. Change the clone entry from 'pKABAg1' to 'TaPK3 {1536} [PKABAg1 {1536}].'.

Amendments:

• Xglk222-2D. Add '5D' in the last column.
• Xglk554-2A,B. Change to 'Xglk554-2A {822,154}1, 2B {822}1, 2D {9926}4.'.
• Xgwm55-2B. Change to 'Xgwm55-2B.2 [{1225}],{9929}', add '[Xgwm55-2B {1225}].' in the second column, and add '(6D).' in the last column.
• Xgwm210-2D {1225}. Change to 'Xgwm210-2B {9929}, 2D {1225}.'.
• Xgwm249-2D. Change to 'Xgwm249-2A {9929}, 2D {1225}'.
• Xgwm410-2B. Add '(5A).' in the last column.
• XksuD8-2D. Move the superscript '1,3' from the marker symbol to the reference.
• XksuF19-2D. Delete the entry (moved to Group 2S).
• XksuF36-2D. Add '7D' in the last column.
• XksuG49-2D.1,.2,.3,.4. Add '7D' in the last column.
• XksuD18-2D(1) [{448}]. Change to 'XksuD18-2D.1,.2 [{448}]. [XksuD18(A)-2D, XksuD18(B)-2D {448}]. pTtksuD18.'.
• XksuD18-2D(2) [{448}]. Delete.
• Xucg1(ACCp)2A,2B,2D. Delete (moved to 2S).

Group 3S

Amendments:

• Xabg460-3A. Add '1D' in the last column.
• Xgwm2-3A. Change to 'Xgwm2-3A {1226}, 3D {9929}.'.
• Xmwg584-3A. Add '1D' and '5D' in the last column.
• Xpsr547-3B. Add '(1D).' in the last column.
• Xpsr946-3A. Add '6D' in the last column.
• Xtam12-3A,B,D. Add '[Xth12-3D {9929}].' in the second column.
• Xtam55-3A,D. Add '[Xth55-3D {9929}].' in the second column.

Amendments:

• Xabc174-3B,D. Change to 'Xabc174-3A {9961}, B,D {1061}.'.
• Xabg377-3A. Add '(6D).' in the last column.
• Xabg387-3A. Add '6A,B' in the last column.
• Xbcd828-3A. Add '(2D).' in the last column.
• Xbg131-3B. Add superscript '1' to '{1061}' and ', 3D {9926}4' in the first column.
• XksuG62-3A,B,D. Delete 'The arm location of XksuG62-3D in T. tauschii was not reported in {448}.' and add the comment 'Eight XksuG62-3D loci were reported in {9926}.'.
• Xmwg802-3A. Add superscript '1' to '{1061}' and ', 3D {9926}4' in the first column.
• Xpsr156(L13)-3A,B,D. Change references to {1329,1392}
• Xpsr1203-3A. Add superscript '1' to '{247}' and ', 3D {9926}4' in the first column.
• Xrsq805(Embp)-3B. Add '(2B).' to last column.
• Xtam33-3A,B,D. Change first column to 'Xtam33-3A,B {245}, 3D {245,9929}.', add '[Xth33-3D {9929}].' in the second column, and add the comment 'The arm locations of Xtam33-3A,B,D were not determined in {245}.'.
• Xwg177-3A. Add superscript '1' to '{1061}' and ', 3D {9926}4' to the first column and remove '4A' from the last column.
• Xwia483(Cxp1)-3A,B,D. Add '(6D).' in the last column.

Group 3

Amendments:

• Xcdo395-3A. Add a superscript '1' to '{1061}' and add ', 3D {9926}4' in the first column.
• Xglk652-3B. Add a superscript '1' to '{822}' and add ', 3D {9926}4' in the first column.
• Xglk756-3B. Add '2D' and '5D' in the last column.
• Xtam32-3A,B,D. Delete (moved to 3L).

Group 4S (4AL:4BS:4DS)

Amendments:

• Xcdo669-4A,B,D. Add '7D' in the last column.
• Xgwm165-4B. Delete (moved to 4AS:4BL:4DL).
• XksuG12-4A. Add '7D' in the last column.
• Xmwg634-4B,D. Add '(4A,B, 7D).' in the last column.
• Xwg184-4D. Add '(2D, 3D).' in the last column.
• Xwg909-4B. Add '(5A,B,D, 7B).' in last column.

4AmS.

Amendments:

• abg387-4A. Change last column to '(1A,B,D, 3A, 5A, 6A,B).'.
• Xabg460-4A.1. Add '1D' in the last column.
• Xcdo669-4A. Add '7D' in the last column.
• Xmwg584-4A.1. Add '1D' and '5D' in the last column.

Group 4L (4AS:4BL:4DL)

Amendments:

• Xabg484-4A,B. Add '(4AmL, 6D).' in the last column.
• Xcdo1312-5A,4B,D. Add '5D' in the last column.
• Xcdo1337-4A,B. Add superscript '1' to '{1008}' and ', 4D {9926}4' in the 1st column.
• Xfbb58-4B. Delete (moved to 5AL:4BL:4DL).
• Xgwm165-4D. Change to 'Xgwm165-4A,B {9929}, 4D {117}.' and add the comment 'A 4BS Xgwm165-4B was reported in {724}.'.

4AmL.

Amendments:

• Xabg460-4A.2. Add '1D' in the last column.
• Xabg463-4A. Add '(4D, 5D).' in the last column.
• Xabg484-4A. Add '6D' in the last column.
• Xmwg584-4A.2. Add '1D' and '5D' in the last column.

4AL:4BL:4DL

5AL:4BL:4DL

Amendments:

• Xgwm410-5A. Add '(2B).' in the last column.
• XksuH11-5A, 4B,D. Add '6A' in the last column.

Group 4

Amendments:

• Xfba211-4A {1059}. Change to 'Xfba211-4A {1059}, 4D {9957}.'.
• Xglk335-4B {822}. Delete (moved to 5AL:4BL:4DL).
• Xglk578-4A,B {822}. Change to 'Xglk578-4A,B {822}, 4D {9966}.'.
• XksuB5-4D. Add '(5D).' in the last column.
• XksuG55-4D. Add '2D' in the last column.
• Xmwg634-4A,B. Add '(4BS,DS, 7D).' in the last column.

Amendments:

• Xcdo388-4A. Change last column to '(1B,D, 2B, 3D, 4D, 5A,D, 6A,D).'.
• XksuH8-4A. Change probe symbol to 'pTtksuH8' and add '2D' and '3D' in the last column.
• Xcdo669-4A. Add '7D' in the last column.
• Xmwg584-4A.1. Add '1D' and '5D' in the last column.

Group 5S

Amendments:

• XcsSR3(Gsp)-5A. Delete the entire entry and substitute 'XcsSR3(Gsp)-5A,B,D [{446}]1, 5A {282}3.
  [Xgsp-5A,B,D {446}]. pGsp {1185}. (1D, 7D).'.
• Xglk317-5A.1,.2, 5A. Add '3D' and '4D' in the last column.
• Xglk424-5A. Add '(5D).' in the last column.
• Xgsp-5A,B,D. Delete the entire entry.
• Xgwm129-5A. Add '(2B).' in the last column.
• XksuH8-5A,B. Add '2D' and '3D' in the last column.
• psr946-5D. Add '6D' in the last column.
• Xwg341-5A. Add ', 5D {9926}4' in the first column.

Amendments:

• Xabg387-5A. Add '6A,B' in the last column.
• Xabg391-5A. Add superscript '1' to '{1059}' and add ', 5D {9926}4' in the first column.
• Xabg473-5B. Change to 'Xabg473-5A {9933}1,3, 5B {1059}1.'.
• Xbcd9-5A,B. Add '(6D).' in the last column.
• Xcdo348-5A,B. Add ', 5D {9926}4' in the first column.
• Xcdo388-5A,D. Add '(1B,D, 2B,D, 3D, 4A,D, 6A,D).' in the last column.
• Xcdo786-5A,D. Add '7D' in the last column.
• Xcdo1168-5A. Add ', 5D.1,.2 {9926}4' in the first column.
• Xcdo1312-5B. Add superscript '1' to '{446}' and ', 5D.1,.2 {9926}4' in the first column, and add '(1B, 5A,4B,D)' in the 4th column.
• Xglk222-5B. Revise the first column to 'Xglk222-5B [{446}]1, 5D {9926}4.'.
• Xglk651-5B,D. Add '6D' in the last column.
• Xglk754-5B. Add '(1D).' in the last column.
• XksuD42-5A,B,D. Add '(6D).' in the last column.
• XksuF1-5A,B,D. Change the last column to '(2A,B).'
• XksuG12-5D. Add '7D' in the last column.
• Xmwg522-5A {1059}, pTamwg522-5B {446}. Change the first column to 'Xmwg522-5A {1059}1, 5B {446}1, 5D {9926}4.'.
• Xmwg820-5A. Add '2D' and '6B' in the last column.
• Xrsq805(Embp)-5A,B,D. Add '(2B).' to last column.
• Xttu1937(Wsip16)-5A.1,.2. Delete the entire entry and substitute the following: 'Xttu1937(Wsip16)-5A.1,.2 [{281}]3, 5D {9926}4. [XDhn2-5A.1,.2 {278}, Xttu1937(Wsip16)[XDhn3]-5D {9926}]. pTaWSP16 {662}. (6A).
• The arm location of Xttu1937(Wsip16)-5D' in T. tauschii was not reported in {9926}.'.

4AL:5BL:5DL

Group 5

Amendments:

• Xglk278-5A,B. Add '(2D, 4D).' in the last column.
• Xglk554-5B. Change last column to '(2A,B,D).'.
• Xglk612-5A. Add superscript '1' to '{822}' and ', 5D {9926}4' in the first column.
• Xglk756-5A. Add superscript '1' to '{822}' and ', 5D'{9926}4' in the first column and add '2D' in the last column.
• Xpsr167(Hpr)-5B. Delete (moved to 5L arm group).
• Xwg908-5B. Change last column to '(1A, 5AL,BL,DL).'.

Amendments:

• Xabc173-6D. Change to 'Xabc173-6A {9927}2, 6D {900}1.'.
• Xabg458-6A. Delete and substitute 'Xabg458-6A {282}3, 6B {9927}2, 6D.1,.2 {9926}4. ABG458. (1D).
• The arm locations of Xabg458-6D.1 and Xabg458-6D.1 in T. tauschii were not reported in {9926}.'.
• Xbcd21-6A,B,D. Add '(5A).' in the last column.
• Xcmwg652-6A. Delete and substitute 'Xcmwg652-6A {900}1, 6B {9927}2, 6D {9926}4. cMWG652. (4D).'.
• Xcmwg684-6B. Change to 'Xcmwg684-6B.1', add '[Xcmwg684-6B {1272}].' in the second column, and add '(6AL,BL).' in the last column.
• Xglk547-6D. Add '(5BL).' in the last column.
• XksuG48-6A,B,D . Revise the first column to 'XksuG48-6A,B {187}2, 6D {448}4,{444,862}1.', add '[DG G48 {862}].' in the third column, and add '3B' in the last column.
• XksuG48-6A,D. Delete the entire entry.
• XksuG48-6D. Delete the entire entry.
• XksuH11-6A. Add '(5A, 4B,D, 6D).' in the last column.
• XksuM9S-6D. Add superscript '4' to '{448}' and add '[XksuM9-6D {9926}].' in the second column.
• Xmwg67-6A. Add '(1A).' to last column.
• Xmwg573-6A.2. Change to 'Xmwg573-6A.2 {282}3, 6B {9922}2, 6D {9926}4', and add '(7D).' in the last column.
• Xmwg820-6A. Add '2D' and '6B' in the last column.
• Xmwg916-6D. Change to 'Xmwg916-6A {9927}2, 6D {900}1.'.
• Xpsr106(Cyc)-6A,B,D. Change 'Cyc' to 'Cyp'.
• Xpsr141(Pgk2)-6A,B,D. Add '(7D).' in the last column.
• Xpsr167(Hpr)-6A,B,D. Add 'Xpsr167(Hr)-6D {9926}' in the second column.
• Xrsq805(Embp)-6B. Add '(2B).' in the last column.
• Xtam68-6D. Delete (incorrect entry).

Delete:

• 'XksuG48-6A {900}, 6D [{862}],{900}.
• [XksuG48(A){862}]. pTtksuG48 {448}.
• [DG G48 {862}].'

Amendments:

• Xabc175-6D. Change to 'Xabc175-6A {9927}2, 6D {900}1.'.
• Xabg473-6B. Add '5A' in the last column.
• Xcdo388-6A. Change to 'Xcdo388-6A {900}1, 6D {9926}4.' and revise last column to '(1B,D, 2B, 3D, 4A,D, 5A,D).'.
• Xcdo507-6B. Change to 'Xcdo507-6A {9927}2, 6B {900}1.'.
• Xcdo772-6A. Change to 'Xcdo772-6A {900}, 6B {9921}.'.
• Xcmwg669-6D. Change to 'Xcmwg669-6A,B {9927}2, 6B {900}1' and add '(7D).' in the last column.
• XksuF19. Add ', 6D {9926}4' in the first column and add '(2A,B,D).' in the last column.
• XksuF36-6D, XksuG12-6B and XksuG49-6A. Add '7D' in the last column.
• Xmwg74-6B. Change to 'Xmwg74-6A {9927}2, 6B {900}1.'.
• Xmwg573-6A.1. Revise last column to '(6AS,BS,DS, 7D).'.
• Xmwg798-6A. Change to 'Xmwg798-6A {282}3, 6B {9927}2.'.
• Xpsr546-6B,D. Add '(6AS).' in the last column.
• Xrsq805(Embp)-6A. Add '(2B).' to last column.
• Xwg223-4A,B,D. Change to 'Xwg223-6A,B,D'.
• Xwg286-4A,B,D. Change to 'Xwg286-6A,B,D'.
• Xwg341-6B.1,.2 . Add '5D' in the last column.

Group 6

Amendments:

• Xa-Amy-6D(1),(2),(3). Change to 'Xa-Amy-6D.1,.2,.3 [{448}]4.'.
• Xbcd1426-6B. Delete (moved to 6L).
• Xcdo534-6B, Xcdo1158-6B, and Xcdo1091-6B. Delete (moved to either 6S or 6L).
• Xcdo1380-6B {860}. Add 'A Xcdo1380-6B was mapped in 6BS in {9927} and in 6BL in {9921}.'.
• Xcsb112(Dhn5)-6D. Add '[Xcsp112(Dhn5)-6D {9926}4].' in the second colunmn.
• Xglk317-6A. Add '3D' and '4D' in the last column.
• Xglk259-6A. Add '(1D).' in the last column.
• Xglk334-6A. Delete (moved to 6L).
• Xglk479-6A, Xglk736-6B, Xglk705-6B, and Xglk762-6A. Add a superscript '1' to '{822}' and add ', 6D {9926}4' in the first column.
• Xglk495-6D, Xglk520-6B, Xglk537-6A, Xglk562-6A, Xglk582-6B and Xglk680-6B. Delete (moved to either 6S or 6L).
• Xglk756-6A. Add '2D' and '5D' in the last column.
• Xglk762-6A. Delete (moved to 6L).
• Xksu1-32-4. Change to 'Xksu1-32-4-6D' and add '(3D, 7D).' in the last column.
• XksuH11-6D. Add '6A' in the last column.

Group 7S

Amendments:

• Xabc465-7A. Add ', 7D {9926}4' in the first column.
• Xglk61-7A. Change last column to '(7BL,DL).'.
• Xglk301-7A. Add '(2D, 3D, 5D).' in the last column.
• Xglk651-7A. Add '6D' in the last column.
• Xgwm68-7B. Add '(5B).' in the last column.
• XksuH8-7A,B. Add '2D' and '3D' in the last column.
• Xwg909-7B. Add '4B' in last column.

Amendment:

• Xabg378-7A. Add '(2A, 6A,D). in the last column.
• XksuF36-4A. Add '7D' in the last column.
• XksuF48-7D. Add '(6D).' in the last column.
• XksuG49-4A. Add '7D' in the last column.
• Xpsr946-7A.1,.2,D.1,.2. Add '6D' in the 4th column.

Amendments:

• Xglk61-7B. Add superscript '1' to '{553}' and ', 7D.1,.2 {9926}4' in the first column.
• Xglk197-7B. Add '(2D).' in the last column.
• Xglk301-7A. Add '(2D, 3D, 5D).' in the last column.
• Xglk642-7A. Add '(3D).' in the last column.
• XksuB7-7B,D. Change the first column to 'XksuB7-7B,D {553}1, 7D {448}4.', add '(1D, 3D, 5D).' in the last column, and add 'The arm location of XksuB7-7D in T. tauschii was not reported in {448}.'.
• XksuG12-7A. Add superscript '1' to '{553,154}' and ', 7D {9926}4' in the first column and add the comment 'The arm location of XksuG12-7D in T. tauschii was not reported in {9926}.'.
• XksuH8-7A,D. Add '2D' and '3D' in the last column.
• Xpsr547-7A,B,D. Add '(1D).' in the last column.
• Xpsr680-7A,B,D. Add '(2D).' in the last column.
  Xpsr946-7D.2. Change the first-column entry to 'Xpsr946-7D.3.'.
• Xrsq805(Embp)-7D. Add '(2B).' in last column.
• Xwg341-7A,B,D. Add '5D' in the last column.
• Xwg420-7A,D. Add '(5D).' in the last column.

Group 7

Amendments:

• Xglk356-7B. Add ', 7D {9926}4' in the first column.
• Xglk642-7A. Add '(3D).' in the last column.
• XksuB7-7D. Delete (moved to 7L).
• XksuG55-7A. Add '(1D, 2D, 4D, 7A).' in the last column.
• Xgsp-7D. Delete the entire entry and substitute 'XcsSR3(Gsp)-7D [{757}]4. [Xgsp-7D {757}]. pGsp {757}. (1D, 5A,B,D).'.

Loci controlling flour colour were identified and mapped in a recombinant inbred population derived from hexaploid wheat cultivars Schomburgk and Yarralinka {9936}. Regions in 3A and 7A accounted for 13% and 60% of the genetic variation, respectively, and Xbcd828-3A, Xcdo347-7A and Xwg232-7A.1 were significantly associated with flour colour. The association was highly significant in all three replicates only for the 7A QTL, however. Symbols were not assigned to the flour colour loci.

Gibberellic Acid Response (insensitivity)

Gai1.

Add at end of Gai1 section :
'A 4B gene conferring gibbberellic acid insensitivity was mapped in a cross between durum wheat cv. Messapia and T. turgidum subsp. dicoccoides acc. MG4343. ma: Xpsr622-4B (distal) 1.9 cM Gai1 8.3 cM Xbcd110-4B (proximal) {9959}.'

Glume Colour

1. Red (brown/bronze).

Rg1. Add: v: Diamant I {9906}; T. petrapavlovskyi {9906}. Milturum 321 Rg3 {9906}; Milturum 553 Rg3 {see 9906}; Strela Rg3 {9906}.
Add at end of section:
'A 1B gene controlling red glume colour was mapped in a cross between durum wheat cv. Messapia and T. turgidum subsp. dicoccoides acc. MG4343. ma: Xutv1518-1B (distal) 7.7 cM Rg1 0.8 cM Gli-B1 (proximal) {9959}.'
Rg2. Add: i: Saratovskaya 29*5//T. timopheevii/T. tauschii {9906}.
Rg3. 1AS {add: see 9906}. Add: v: CS/Strela Seln {9906}; Iskra {9906}; Zhnitstra {9906}. Milturum 553 Rg1 {see 9906}; Milturum 321 Rg1 {9906}; Strela Rg1 {9906}.

2. Black.

Add at end of section:
'A 1A gene controlling black glume colour was mapped in a cross between durum wheat cv. Messapia and T. turgidum subsp. dicoccoides acc. MG4343. ma: Xutv1391-1A (distal) 3 cM Bg 1.6 cM Hg 2.4 cM Gli-A1 (proximal) {9959}.'

Hairy Glume

Add at end of section:
'A 1A gene controlling hairy glumes was mapped in a cross between durum wheat cv. Messapia and T. turgidum subsp. dicoccoides acc. MG4343. ma: Xutv1391-1A (distal) 3 cM Bg 1.6 cM Hg 2.4 cM Gli-A1 (proximal) {9959}.'

Height

Reduced height: Ga-insensitive

Rht-D1.

Add at end of first sentence:
'; Rht-D1 2.8 cM Xglk578-4D {9966}.'

Reduced height: GA-sensitive

Rht8.
Add at end of section:
'The close linkage of Rht8 and Xgwm261-2D permitted the use of the microsatellite as a marker for the detection of allelic variants at the Rht8 locus {9962}.
Rht8a. Associated with a 165-bp fragment of WMS 261 {9962}. v: Autonomia {9962}; Bobwhite {9962}; Brevor {9962}; Chaimite {9962}; Ciano 67 {9962}; Chris {9962}; Dugoklasa {9964}; Federation {9962}; Frontana {9962}; Glennson 81 {9962}; Jupateco 73 {9962}; Kenya {9962}; Klein 32 {9962}; Lerma Rojo {9962}; Lusitano {9962}; Maringa {9962}; Mentana {9962}; Nainari 60 {9962}; Newthatch {9962}; Opata 85 {9962}; Othello {9962}; Penjamo 62 {9962}; Quaderna {9962}; Rex {9962}; Riete {9962}; Saitama 27 {9962}; Spica {9962}; Veery S {9962}; Victo {9962}.
Rht8b. Associated with a 174-bp fragment of WMS 261 {9962}. v: Balkan {9962}; Bunyip {9962}; Cappelle-Desprez {9962}; Eureka {9962}; Festival {9962}; Fronteira {9962}; Fultz {9962}; Gabo {9962}; Heine VII {9962}; Inallettabile 95 {9962}; Jena {9962}; Klein Rendidor {9962}; Leonardo {9962}; Lutescens 17 {9962}; Mironovskaya 808 {9962}; Norin 10 {9962}; Norin 10/Brevior 14 {9962}; Podunavka {9962}; Record {9962}; Red Coat {9962}; Soissons {9962}; Talent {9962}; Tevere {9962}; Timstein {9962}; Wilhelmina (9962}.
Rht8c. Associated with a 192-bp fragment of WMS 261 {9962}. v: Alfa {9962}; Aquila {9962}; Ardito {9962}; Argelato {9962}; Avrora {9962}; Banija {9964}; Baranjka {9964}; Beauchamps {9962}; Bezostaya {9962}; Biserka {9962}; Campodoro {9962}; Centauro {9962}; Chikushi-Komugi (Norin 121) {9962}; Damiano {9962}; Djerdanka {9964}; Dneprovskaya {9962}; Duga {9964}; Etoile-de-choisy {9962}; Etruria {9962}; Fakuho-Kumugi (Norin 124) {9962}; Farnese {9962}; Favorite {9962}; Fiorello {9962}; Fortunato {9962}; Funo {9962}; Gala {9962}; Haya Komugi {9962}; Impeto {9962}; Irnerio {9962}; Jarka {9964}; Jugoslavia {9962}; Kavkas {9962}; Kolubara {9964}; Kosava {9964}; Libellula {9962}; Lonja {9964}; Lovrin 32 {9962}; Macvanka-2 {9964}; Mara {9962}; Marzotto {9962}; Neretva {9962}; Nizija {9962}; N.S. Rana1 {9962}; N.S. Rana 2 {9962}; N.S. 649 {9962}; N.S. 3014 {9962}; Orlandi {9962}; Osjecanka {9964}; OSK 5 5/15 {9964}; OSK 4 57/8 {9964}; OSK 3 68/2; Partizanka {9962}; Partizanka Niska {9962}; Poljarka {9964}; Posavka 1 {9964}; Posavka 2 {9962}; Pomoravka {9962}; Produttore {9962}; Radusa {9962}; Salto {9962}; Sanja {9962}; San Pastore {9962}; Sava {9962}; Siette Cerros {9962}; Sinvaloche {9962}; Skopjanka {9962}; Skorospelka 3B {9962}; Slavonija {9964}; Somborka {9964}; Sremica {9964}; Superzlatna {9962; Tisa {9964}; Transilvania {9962}; Una {9962}; Villa Glori {9962}; Zagrebcanka {9964}; Zelengora {9964}; ZG 6103/84 {9964}; ZG 7865/83 {9964}; Zitarka {9964}; Zitnica {9962}; Zlatna Dolina {9964}; Zlatoklasa {9964}; Svezda {9962}.
Rht8d. Associated with a 201-bp fragment of WMS 261 {9962}. v: Pliska {9962}; Courtot {9962}.
Rht8e. Associated with a 210-bp fragment of WMS 261 {9962}. v: Chino {9962}; Klein Esterello {9962}; Klein 157 {9962}.
Rht8f. Associated with a 215-bp fragment of WMS 261 {9962}. v: Klein 49 {9962}.'
Add a new section at the bottom of the height section :
'Reduced Height
QTL loci mapped include:
QHt.fra-1A [{9957}]. ma: Linkage with Xfba393-1A.
QHt.fra-1B [{9957}]. ma: Linkage with Xcdo1188-1B.2.
QHt.fra-4B [{9957}]. ma: Linkage with Xglk556-4B.
QHt.fra-7A [{9957}]. ma: Linkage with Xglk478-7A.
QHt.fra-7B [{9957}]. ma: Linkage with XksuD2-7B.'

Proteins

2. Enzymes

2.6. Endopeptidase

Ep-A1d {894}. Isozyme 6. v: PI 294994 {894}.
Ep-D1e {894}. Isozyme 5. v: PI 294994 {894}.

2.20. Aromatic alcohol dehydrogenase

Aadh-A1.

Add at bottom of Aadh-A1 section: 'ma: XksuG44-5A (proximal) 6.9 cM Aadh-A1 24.7 cM Xcdo412-5A (distal) {9959}.'

2.29. Starch branching enzyme

SbeI1 {9937}. 1DL {9937}. v: CS {9937}.
SbeI2 {9937}. 7BL {9937}. v: CS {9937}.

3. Endosperm Storage Proteins

3.1. Glutenins
At the end of the Glu-B1 section, delete
'Variation in the staining intensity of subunit 7 in different varieties has also been observed {1069}; possible low gene expression at Glu-B1 has been noted for Glu-B1w, where subunits 6*+8* stain very faintly {1146}.'
and substitute
'Variation in the staining intensity of subunit 7 in different varieties has also been observed {1069}; a duplication of the gene encoding subunit 7 has probably occurred in cultivar `Red River 68', as evidenced by increased intensity of the subunit in SDS-PAGE and by approximately doubled intensity of restriction fragments carrying the gene in Southern blotting {9989}. Possible low gene expression at Glu-B1 has been noted for Glu-B1w, where subunits 6*+8* stain very faintly {1146}.'.

3.2. Gliadins

Revision of preamble:
Delete
'Variation at the Gli-1 loci was described earlier {634,996,1126} and applied in mapping experiments {1243,1125,196,422,1120}. A rational system of naming the alleles was produced by E.V. Metakovsky, N.I. Vavilov Institute of General Genetics, Moscow {988}. This nomenclature is reproduced below. Where two cultivars are given as prototypes for an allele, the first named is from the USSR and the second from elsewhere.'
and substitute
'Variation at the Gli-1 loci was described earlier {634,996,1126} and applied in mapping experiments {1243,1125,196,422,1120}. A rational system of naming the alleles has been produced by Dr. E.V. Metakovsky (Present Address: Unidad de Genética, Departamento de Biotecnologia, E.T.S.I. Agrónomos, Universidad Politecnica de Madrid, 28040 Madrid, Spain) {988}. This nomenclature is reproduced below. A considerable number of alleles have been added to the original list given in {988}, and referenced here accordingly. A few alleles have been deleted, because, following much detailed comparison, there is now doubt that they can be reliably distinguished from existing alleles {9981}; for the moment, however, the allelic letter in these cases has not been reused. To facilitate practical use of the list, the aim has been to give at least three standard cultivars from a range of countries for each allele {9981}. This has been achieved for the vast majority of entries and is a change from the original list compiled from {988}, where up to two standards were given. While the three or more standards described almost always include the original standards, some have been replaced for various reasons, such as international awareness of the cultivar, availability of seed, or the ease with which an allele can be identified in a particular genetic background {9981}. In the original list, where two cultivars were given as prototypes for an allele, the first named was from the USSR and the second from elsewhere; this is no longer the case, although pains have been taken to include a Russian cultivar where possible, to maintain the base of germplasm in which the alleles are available to be as wide as possible, as well as to acknowledge the research groups in the country where much of the pioneering work was carried out.
For discussion of null alleles at the Gli-1 and Gli-2 loci, see {9984}.'.
Delete the following from the preamble:
'A number of novel gliadin alleles were reported in {991}; they will be included in the next supplement to the catalogue.'
At the end of the preamble, delete
'The Gli-1 loci may be recognised by probes pcP387 {372} and pTag1436 {065}, and by specific microsatellite primers {252}.'
and substitute
'The Gli-1 loci may be recognised by probes pcP387 {372} and pTag1436 {065}, and by specific microsatellite primers {252}. Furthermore, it has been shown that probe pTag1436 differentiates gliadin alleles rather well; using this probe, families of gliadin alleles and some of their relationships have been described {9988}.'.

Gli-A1

Delete the previous corresponding entries and substitute the following:
Gli-A1a {988}. v: CS {988}; Castan {991}; Mentana {9986}; Mara {9986}.
Gli-A1b {988}. v: Bezostaya 1{988}; Mercia {988}; Tracy {991}.
Gli-A1c {988}. v: Ukrainka {988}; Gazul {9985}; Sava {994}.
Gli-A1d {988}. v: Dankowska {988}; Cabezorro {9985}.
Gli-A1e {988}. v: Open {991}; Touzelle {991}; Falchetto {988}.
Gli-A1f {988}. v: Maris Freeman {988}; Mironovskaya 808 {988}; Arminda {991}.
Gli-A1g {988}. v: Gabo {988}; Adalid {9985}.
Gli-A1h {988}. v: Sadovo I {988}; Predela {9981}; Krajinka {9981}.
Gli-A1i {988}. v: Saratovskaya 36 {988}.
Gli-A1j {988}. v: Lutescens 62 {988}.
Gli-A1k {988}. v: Courtot {991}; Soissons {991}; Spada {9986}; Skala (heterogeneous) {988}.
Gli-A1l {988}. v: Lesostepka 75 {988}; David {9986}; Salmone {9986}; Mura {9981}.
Gli-A1m {988}. v: Marquis {988}; Dneprovskaya 521 {988}; Carat {991}; Liocorno {9986}.
Gli-A1n {988}. v: Intensivnaya {988}.
Gli-A1o {988}. v: Cappelle-Desprez {991}; Capitole {991}; Oderzo {9986}; Odesskaya 16 (heterogeneous) {988}.
Gli-A1p {988}. v: Pyrotrix 28 {988}; Zagore {9981}.
Gli-A1q {988}. v: Akmolinka 1 {988}.
Gli-A1r {988}. v: Ranniaya 73 {988}; Barbilla {9985}.

Omission:
Gli-A1s.
Gli-A1s, not previously listed in the catalogue but reported in {9986}, is omitted from the catalogue temporarily because its status is in need of further confirmation {9981}.

Add:
Gli-A1t {9985}. v: Jeja del País {9985}.
Gli-A1u {9985}. v: Candeal Alcala {9985}.
Gli-A1null {9984,9987}. v: Saratovskaya 29 (mutant) {9987}; E.Mottin {9981}.

Gli-B1

Delete the previous corresponding entries and substitute the following:
Gli-B1a {988}. v: CS {988}.
Gli-B1b {988}. v: Bezostaya 1 {988}; Marquis {988}; Soissons {991}; Carat {991}; Liocorno {9986}.
Gli-B1c {988}. v: Siete Cerros 66 {988}; Prinqual {991}; Loreto {9986}.
Gli-B1d {988}. v: Chopin {991}; Dneprovskaya 521 {988}; Petrel {991}; Tiberio {9986}; Yécora {9985}.
Gli-B1e {988}. v: Lutescens 62 {988}; Apexal {991}; Fournil {991}; Oderzo {9986}.
Gli-B1f {988}. v: Maris Freeman {988}; Dankowska {988}; Mercia {988}; Cappelle-Desprez {991}; Capitole {991}.
Gli-B1g {988}. v: Galahad {988}; Sadovo 1 {988}; Champtal {991}; Tracy {991}; Mara {9986}.
Gli-B1h {988}. v: Krasnodonka {988}; Pepital {991}; Rudi {991}; Cabezorro {9985}.
Gli-B1i {988}. v: Insignia {988}; Ghurka {988}.
Gli-B1j {988}. v: Cluj 650 {988}.
Gli-B1k {988}. v: Mentana {9986}; Kremena {988}; De Carolis {9986}; Crvenkapa {994}.
Gli-B1l {988}. v: Clement {991}; Damier {991}; Fiocco {9986}.
Gli-B1m {988}. v: Pyrotrix 28 {988}; Et.d'Choisy {991}; Costantino {9986}.
Gli-B1n {988}. v: Intensivnaya {988}.
Gli-B1o {988}. v: Pippo {9986}; Levent {988}; Aragón 03 {9985}; San Rafael {9985}.
Gli-B1p {988}. v: New Pusa 834 {988}; Inia 66 {9985}.
Gli-B1q {9986}. v: Goelent {991}; Goya {991}; Gallo {9986}.
Gli-B1r {995}. v: Gazul {9985}; Sevillano {9985}; Chinook {995}.

Add:
Gli-B1s {9986}. v: Salmone {9986}; Resistente {9986}; E.Mottin {9981}.

Omission:
Gli-B1t.
Gli-B1t, not previously listed in the catalogue but reported in {9986}, is omitted from the catalogue temporarily because its status is in need of further confirmation {9981}.

Add:
Gli-B1u {9985}. v: Negrillo {9985}.
Gli-B1v {9985}. v: Montjuich {9985}.
Gli-B1null {9984,9987,991}. v: Touzelle {991}; Florence Aurora {9985}.

Gli-D1

Delete the previous corresponding entries and substitute the following:
Gli-D1a {988}. v: CS {988}; Marquis {988}; Saratovskaya 36 {988}; Mentana {9986}; Prinqual {991}.
Gli-D1b {988}. v: Bezostaya 1 {988}; Galahad {988}; Cappelle-Desprez {991}; Et.d'Choisy {991}.
Gli-D1c {988}. v: Skorospelka Uluchshennaya (biotype) {988,9982}.
Gli-D1d {988}. v: De Carolis {9986}; Solo {988}.
Gli-D1e {988}. v: Gerek 79 {988}.
Gli-D1f {988}. v: Maris Freeman {988}; Gabo {988}; Carlos {991}; Orso {9986}.
Gli-D1g {988}. v: Ghurka {988}; Mironovskaya 808 {988}; Fournil {991}; Open {991}.
Gli-D1h {988}. v: Sadovo 1 {988}; Zlatostrui {9981}.
Gli-D1i {988}. v: Insignia {988}; Tselinogradka {988}; Napayo (biotype) {995}; San Rafael {9985}.
Gli-D1j {988}. v: Aubain {991}; Promin {988}; Petrel {991}; Inia 66 {9985}; Chinook {995}.
Gli-D1k {988}. v: Mara {9986}; Pippo {9986}; Kremena {988}; Cargimarec {991}.
Gli-D1l {988}. v: Longbow {988}; Artaban {991}; Corin {991}.

Add:
Gli-D1m {991}. v: Heurtebise {991}.
Gli-D1n {9981}. v: Blanquillo de Toledo {9985}.
Gli-D1null {9984,9987,991}. v: Darius {991}; Touzelle {991}; Saratovskaya 29 (mutant) {9987}.

Gli-A2

Delete the previous corresponding entries and substitute the following:
Gli-A2a {988}. v: CS {988}; Insignia {988}; Rieti DIV {9986}; Cabezorro {9985}.
Gli-A2b {988}. v: Bezostaya 1 {988}; Rivoli {991}; Tiberio {9986}; Aradi {9985}.
Gli-A2c {988}. v: Siete Cerros 66 {988}; Prinqual {991}; Loreto {9986}; Escualo {9985}.
Gli-A2d {988}. v: Dneprovskaya 521 {988}; Mocho Sobarriba {9985}.
Gli-A2e {988}. v: Sadovo 1 {988}; Cobra {991}; Mentana {9986}; Resistente {9986}; Sevillano {9985}.
Gli-A2f {988}. v: Maris Freeman {988}; Gala {991}; Sistar {9986}; Adalid {9985}.
Gli-A2g {988}. v: Cappelle-Desprez {991}; Ducat {988}; Mara {9986}; Mahissa 1 {9985}.
Gli-A2h {988}. v: Hereward {988}; Apollo {991}; N.Strampelli {9986}; Montjuich {9985}.
Gli-A2i {988}. v: Lesostepka 75 {988}.
Gli-A2j {988}. v: Recital {991}; Camp Remy {991}; Avalon {9981}; E.Mottin {9981}.
Gli-A2k {988}. v: Pyrotrix 28 {988}; Akmolinka 1 {988}; Estica {991}; Renan {991}; Zena {9986}.
Gli-A2l {988}. v: Longbow {988}; Champlein {991}; Chamorro {9985}.
Gli-A2m {988}. v: Marquis {988}; Rex {991}.
Gli-A2n {988}. v: Mironovskaya 808 {988}.
Gli-A2o {988}. v: Castan {991}; Touzelle {991}; Lontra {9986}; Calatrava {9985}.
Gli-A2p {988}. v: Capitole {991}; Pliska {988}; Clement {991}; S.Lorenzo {9986}; Cajeme 71 {9985}; Yecora {9985}.
Gli-A2q {988}. v: Saratovskaya 39 {988}; Montcada {9985}; Candeal Alcalá {9985}.
Gli-A2r {988}. v: Riband {988}; Open {991}; Genial {991}.
Gli-A2s {988}. v: Saratovskaya 36 {988}.
Gli-A2t {988}. v: Courtot {991}; Soissons {991}; Rinconada {9985}; Prostor {9981}.
Gli-A2u {988}. v: Titien {991}; Aragon 03 {9985}; Kirgizskaya Yubileinaya {988}; Saunders {995}.
Gli-A2v {988}. v: Kzul-Bas {988}.
Gli-A2w {88}. v: Bezenchukskaya 98 (biotype) {988}.
Gli-A2x {988}. v: Solo {988}.

Add:
Gli-A2y {9981}. v: Gentil Rosso 202 {9981}; PI 191245 {9981}.
Gli-A2z {9986}. v: Gallo {9986}; Giuliana {9986}.
Gli-A2aa {9985}. v: Navarro 122 {9985}.
Gli-A2ab {9985}. v: Navarro 150 {9985}.
Gli-A2null {9984,9987}. v: Saratovskaya 29 (mutant) {9987}.

Gli-B2

Delete the previous corresponding entries and substitute the following:
Gli-B2a {988}. v: CS {988}.
Gli-B2b {988}. v: Bezostaya 1 {988}; Cobra {991}; Sideral {991}; Gladio {9986}.
Gli-B2c {988}. v: Siete Cerros 66 {988}; Gabo {988}; Courtot {991}; Prinqual {991}; Loreto {9986}; Manital {9986}; Sinton {995}; Escualo {9985}; Yecora {9985}.
Gli-B2d {988}. v: Akmolinka 1 {988}; Tselinnaya 20 {988}; Friedland {991}.
Gli-B2e {9986}. v: Veronese {9986}; Arsenal {991}; Zlatna Dolina {994}.
Gli-B2f {988}. v: Maris Freeman {988}; Master {991}.
Gli-B2g {988}. v: Galahad {988}; Cappelle-Desprez {991}; Capitole {991}; Forlani {9986}.
Gli-B2h {988}. v: Mentana {9986}; Sadovo 1 {988}; Castan {991}; Sistar {9986}; Pane 247 {9985}; Partizanka {994}.
Gli-B2i {988}. v: Insignia {988}; Ghurka {988}.
Gli-B2j {988}. v: Farnese {9986}; Funo R250 {9986}; Novosadska Rana 1 {994}.
Gli-B2k {988}. v: Skala {988}.
Gli-B2l {988}. v: Longbow {988}; Tracy {991}; Clement {991}.
Gli-B2m {988}. v: Mironovskaya 808 {988}; Open {991}; Renan {991}.
Gli-B2n {988}. v: Solo {988}.
Gli-B2o {988}. v: Mara {9986}; Hardi {9981}; Rivoli {991}; Pippo {9986}; Slavianka {9981}; Odesskaya 16 {988}.
Gli-B2p {988}. v: Champtal {991}; Oderzo {9986}; Recital {991}; Gazul {9985}; Pliska {988}.
Gli-B2q {988}. v: Saratovskaya 39 {988}.
Gli-B2r {991}. v: Genial {991}; Arminda {991}; Jeja del País {9985}.
Gli-B2s {988}. v: Saratovskaya 36 {988}.
Gli-B2t {988}. v: Tselinogradka {988}.
Gli-B2u {988}. v: Kirgizskaya Yubileinaya {988}.
Gli-B2v {988}. v: Garant {991}; Libellula {9986}; Mahissa 1 {9985}; Poljarka {988}; Declic {991}.
Gli-B2w {995,9986}. v: Rieti DIV {9986}, Palata {9986}, Pembina {995}.

Add:
Gli-B2x {994}. v: Super Zlatna (biotype) {994}; Prostor {9981}; 251/83 {9981}.
Gli-B2y {9986}. v: Centauro {9986}; E.Morandi {9986}.
Gli-B2z {9985}. v: Maestro {9985}.
Gli-B2aa {9986}. v: Salmone {9986}; E.Mottin {9981}.

Omission:
Gli-B2ab.
Gli-B2ab, not previously listed in the catalogue but reported in {991}, is omitted from the catalogue because its status is in need of further confirmation {9981}.

Add:
Gli-B2ac {991}. v: Scipion {991}; Artaban {991}; Riol {991}; Lontra {9981}.
Gli-B2ad {991}. v: Champion {991}; Chopin {991}.
Gli-B2ae {991}. v: Priam {991}; Et.d'Choisy {991}; Campeador {9985}; Krajinka (biotype) {994}.
Gli-B2af {9985}. v: Montjuich {9985}; Mocho Sobarriba {9985}.
Gli-B2null {9984,9987}. v: Saratovskaya 29 {9987}.

Gli-D2

Delete the previous corresponding entries and substitute the following:
Gli-D2a {988}. v: CS {988}; Maris Freeman {988}; Tracy {991}; Sistar {9986}.
Gli-D2b {988}. v: Bezostaya 1 {988}; Cobra {991}; Farnese {9986}; Partizanka {994}.
Gli-D2c {988}. v: Siete Cerros 66 {988}; Eridano {9986}; Rieti DIV {9986}; Escualo {9985}.
Gli-D2d {988}. v: Dneprovskaya 521 {988}.
Gli-D2e {988}. v: Mironovskaya 808 {988}; Open {991}; Dollar {9985}; Lada {9981}.
Gli-D2f {988}. v: Rempart {991}; Créneau {991}; Kirgizskaya Yubileinaya {988}; Skorospelka Uluchshennaya {988}.
Gli-D2g {988}. v: Capelle-Desprez {991}; Futur {991}; Galahad {988}; Ghurka {988}; Mec {9986}.
Gli-D2h {988}. v: Capitole {991}; Garant {991}; Thatcher {995}; Chinook {995}; Sadovo 1 {988}.
Gli-D2i {988}. v: Insignia {988}; Lario {9986}.
Gli-D2j {988}. v: Mentana {9986}; Inia 66 {9985}; Gallo {9986}; Arcane {991}; Gazul {9985}.
Gli-D2k {988}. v: Skala {988}; Cabezorro {9985}; Crvencapa {994}.
Gli-D2l.
Gli-D2l is deleted from the catalogue because it has been shown not to demonstrate reliable differences compared with existing alleles {9981}.
Gli-D2m {988}. v: Marquis {988}; Rex {991}; Veronese {9986}; Yecora {9985}; Rinconada {9985}.
Gli-D2n {988}. v: Mercia {988}; Castan {991}; Pippo {9986}; Mahissa 1 {9985}; Champlein {991}.
Gli-D2o {988}. v: Omskaya 12 {988}.
Note: cultivars Salmone and Resistente, which carry Gli-D2aa {9981}, were erroneously given as standards for allele Gli-D2o in {9986}.
Gli-D2p {988}. v: New Pusa {988}.
Gli-D2q {988}. v: Soissons {991}; Fournil {991}; E.Mottin {9981}; Volshebnitsa (biotype) {988}.
Gli-D2r {988}. v: Mara {9986}; Montcada {9985}; Kremena {988}.
Gli-D2s {988}. v: Akmolinka1 {988}; Bezenchukskaya 98 {988}; Selkirk (biotype) {995}.

Add:
Gli-D2t {9986}. v: Golia {9986}; Gabo {9981}; Manital {9986}; Bokal {9981}.
Gli-D2u {9986}. v: Loreto {9986}; Martial {991}; Cibalka {9981}.
Gli-D2v {991}. v: Epiroux {991}; Arbon {991}.
Gli-D2w {9985}. v: Navarro 150 {9985}; Javelin {9981}; Hopps {9981}; Canaleja {9985}.
Gli-D2x {9985}. v: Montjuich {9985}; Blanquillo {9985}.
Gli-D2y {9985}. v: Candeal Alcalá {9985}.
Gli-D2z {9985}. v: Aragon 03 {9985}.
Gli-D2aa {9981}. v: Salmone {9981}; Resistente {9981}.
Gli-D2null {9984,9987}. v: Saratovskaya 29 (mutant) {9987}.

Gli-A3

Add:
Gli-A3a {9983}. v: CS, Prinqual, Courtot, Tselinogradka, Bezenchukskaya 98.
Gli-A3b {9983}. v: Bezostaya 1.
Gli-A3c {9983}. v: Anda.
Gli-A3d {9983}. v: Saratovskaya 210, Kharkovskaya 6, Richelle.
Each of the above Gli-A3 alleles, apart from Gli-A3d, which is a null, controls one minor omega-gliadin with molecular mass about 41k that occurs in the middle of the omega-region of APAGE fractionation. Gliadins controlled by these alleles differ in their electrophoretic mobility in APAGE in that the fastest of three known Gli-A3-gliadins is controlled by Gli-A3a and the slowest by Gli-A3c {9983}.
In the paragraph that begins, 'It is not clear how Gli-Sl4 and Gli-Sl5 relate to ...',
delete
'It has yet to be established whether this is one of a series of orthologous loci.
Gli-A4 {1205}. 1AS {1205}. v: Perzivan biotype 2.
Dubcovsky et al. {277} did not find evidence for the simultaneous presence of both Gli-A3 and Gli-A4 in five 1A or 1Am mapping populations and concluded that Gli-A4 should be considered to be Gli-A3 until conclusive evidence for the former is obtained.'
and substitute
'However, Metakovsky et al. {9983} have since shown that this locus and Gli-A3 are, in fact, the same locus. Furthermore, Dubcovsky et al. {277} did not find evidence for the simultaneous presence of both Gli-A3 and Gli-A4 in five 1A or 1Am mapping populations and concluded that Gli-A4 should be considered to be Gli-A3 until conclusive evidence for the former is obtained. For these reasons, the locus Gli-A4 is deleted from the catalogue.'.
In the paragraph that begins, 'A locus designated Gli-5 controlling omega-gliadins was mapped ....',
delete
'An estimate for the map distance between Gli-A5 and Gli-A1 was not reported, although evidence was provided that the linkage is of a similar order of magnitude to the Gli-B5 - Gli-B1 distance. Although no orthologous locus was reported for chromosome 1D, the authors cited studies {992,987} reporting a recombination distance of 1 % between two gliadin loci on chromosome 1D, which they considered may have been due to the presence of a locus on 1D orthologous to Gli-B5.'
and substitute
'An estimate for the map distance between Gli-A5 and Gli-A1 was not reported, although evidence was provided that the linkage is of a similar order of magnitude to the Gli-B5 Gli-B1 distance, and, since then, Gli-A5 has been shown to be tightly linked (0-2%) to Gli-A1 {9983}. Although no orthologous locus was reported for chromosome 1D, the authors cited studies {992,987} reporting a recombination distance of 1 % between two gliadin loci on chromosome 1D, which they considered may have been due to the presence of a locus on 1D orthologous to Gli-B5.'.
Gli-A5
Add:
Gli-A5a {9983}. v: CS.
Gli-A5b {9983}. v: Marquis.
Gli-A5a is null. Allele Gli-A5b controls two slow-moving, easily-recognizable omega-gliadins. It is present in all common wheat cultivars having alleles Gli-A1m and Gli-A1r (and, probably, in those having Gli-A1e, Gli-A1l and Gli-A1q), because earlier (for example, in {988}) two minor omega-gliadina encoded by Gli-A5b were considered to be controlled by these Gli-A1 alleles {9983}.
Gli-B5
Add:
Gli-B5a {1147}. v: CS.
Gli-B5b {1147}. v: Salmone.
The situation is fully analogous with Gli-A5: There are currently two alleles differing in the presence/absence of two minor omega-gliadins. Gli-B5a is null. In {988}, omega-gliadins controlled by Gli-B5 (allele Gli-B5b) were attributed to alleles at the Gli-B1 locus (alleles Gli-B1c, i, k, m, n and o).
Add:
Gli-A6 {9983,993}. 1AS {9983}.
Gli-A6a {9983}. v: CS, Bezostaya 1.
Gli-A6b {9983}. v: Bezenchukskaya 98.
Gli-A6c {9983}. v: Courtot, Anda, Mironovskaya 808.
Gli-A6 was first explicitly described in {9983}, but it is now known that it was first observed without designation in {993}. There is strong evidence that it is distinct from Gli-A3 and Gli-A5, mapping distally to Gli-A1, with which it recombines at a frequency of 2-5%. Currently three alleles are known, of which Gli-A6c is particularly well-described in {9983}: the molecular mass of the omega-gliadin controlled by this allele is slightly lower than those of the omega-gliadins controlled by Gli-A3 alleles. In {988}, the omega-gliadin controlled by Gli-A6c was attributed to Gli-A1f. Gli-A6c is rather frequent in common wheat and may relate to dough quality (preliminary data {9983}). Gli-A6a is null {9983}.
Delete from end of gliadin section:
'The Gli-1 loci may be recognised by pcP387 {372}, pTag1436 {066} and by specific microsaellite primers {252}.'

5. Other proteins

5.1. Lipopurothionins

Pur-A1
Add at end of section: 'A PCR marker specific for Pur-A1 was developed in {9976}.'
Pur-B1
Add at end of section: 'A PCR marker specific for Pur-B1 was developed in {9976}.'
Pur-D1
Add at end of section: 'A PCR marker specific for Pur-D1 was developed in {9976}.'
Pur-R1
Add at end of section: 'A PCR marker specific for Pur-R1 was developed in {9976}.'

5.6. Waxy Proteins

Add: 'Lists of cultivars, lines and landraces of tetraploid and hexaploid wheats with different, mostly null, alleles at the Wx loci are given in {9910,9911,9912,1053,1054,9913,9915,9916,1650,9917}.'

Quality Parameters

1. Sedimentation Value

Qsev.mgb-6A {9920}.
6AL{9920}. tv: Nessapia/T. dicoccoides MG4343 mapping population {9920}. ma: Associated with Xrsq805-6A {9920}.
Qsev.mgb-7A {9920}.
7BS {9920}. tv: Messapia/T. dicoccoides MG4343 mapping population {9920}. ma: Associated with Xpsr103-7A {9920}.

Response to Vernalization

Vrn-A1. ma: Vrn-A1 0.8 cM Xbcd450-5A, rg395 4.2 cM Xpsr426-5A {9903}.
Last paragraph: {add: 1173, 9902}.
Add final paragraph: 'New combinations of vrn alleles from Mironovskaya 808 with a high vernalization requirement and Bezostaya 1 with a lower requirement gave progenies with higher and lower vernalization requirements than the respective parents {9902}. The allelic variants were designated with subscripted letters vrn1 B , vrn2 B , vrn3 B and vrn1 M , vrn2 M , vrn3 M . Multiple alleles also were reported in {9930}, and the dominant allele of Novosibirskaya 67 and the weaker dominant allele of Pirotrix 28 were designated Vrn1a and Vrn1b, respectively.'

Restorers for Cytoplasmic Male Sterility

1. Restorers for T. timopheevi cytoplasm

Rf3. ma: Distal....Xcdo388-1B 1.2 cM Rf1 2.6 cM Xabc156-1B....Proximal {9934}.

Ribosomal RNA

5S rRNA genes

5S-Rrna-B1.
Add at end of section: 'A PCR marker specific for 5S-Rrna-B1 was developed in {9974}.'
5S-Rrna-D1.
Add at end of section: 'A PCR marker specific for 5S-Rrna-D1 was developed in {9974}.'
5S-Rrna-R1.
Add at end of section : 'A PCR marker specific for 5S-Rrna-R1 was developed in {9974}.'

Segregation Distortion

QSd.ksu-1D {9931}. 1DL {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with Xcmwg706-1D {9931}.
QSd.ksu-3D {9931}. 3DS {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc TA1704 {9925}. ma: Association with Xwg177-3D {9931}.
QSd.ksu-4D {9931}. 4DS {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with XksuF8-4D {9931}.
QSd.ksu-5D.1 {9931}. 5D {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with Xcdo677-5D {9931}.
QSd.ksu-5D.2 {9931}. 5DL {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with Xglk614-5D (synonym 'Xtag614-5D') {9931}.
QSd.ksu-5D.3 {9931}. 5DL {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with Xwg1026-5D {9931}.
QSd.ksu-7D {9931}. 7DS {9931}. dv: Ae. tauschii var. meyeri acc. TA1691/var. typica acc. TA1704 {9925}. ma: Association with Xglk439-7D (synonym 'Xtag439-7D'') {9931}.

Tiller Inhibition

tin1. [Tin {1212}].
tin2. [Tin {9909}]. Tiller-reducing affect of this allele was dominant {9909}. 2A {9909}. v: 88 F2 185 {9909}.

Pathogenic Disease/Pest Reaction

Reaction to Diuraphis noxia

Dn2.

Add at end of ma: 'Myburg et al. {9968} identified two SCAR markers that mapped 3.3 cM proximal to Dn2.'
Dn7 {9918}. 1B = T1BL·1RS {9918}, 1R {9918}. v: 93M45-14 {9918}.

Reaction to Erysiphe graminis

Pm25 {1343}. [PmTmb {1344}]. 1A {1343}. v: NC94-3778 {1344}. NC96BGTA5 = Saluda*3/PI 427662 Pm3a {1343}. dv: T. monococcum PI 427662 {1343}. ma: Linked with 3 RAPDs, the nearest, OPAG04 950 , at 12.8 ± 4.0 cM {1343}.

Reaction to Fusarium graminearum

QFhs.ndsu.2A {9925}. 2AL {9925}. v: Sumai 3 {9925}. ma: Association with RFLP XksuH16-2A {9925}.
QFhs.ndsu.3B {9925}. 3BS {9925}. v: Stoa {9925}. ma: Association with AFLP XEagcMcta.1 {9925}.

Reaction to Heterodena avenae

Replace current listing with:
Cre2 {238}. Derived from Ae ventricosa 10 {238,9990}. 6M v {9990}. Although H93-8 is a double M v (5A), 7M v (7D) substitution line, Cre2 was presumed to be located in a separate undetected translocated 6M v segment {9991}.

Reaction to Mayetiola destructor (Say)

H21. ma: A RAPD amplified by primer OPE-13 was shown to co-segregate with H21 {9938}.

Reaction to Pseudocercosporella herpotrichoides (Fron) Deighton

Pch DV {618}. 4VL {618}. Change s: to su: and replace as 4VL(4D), Yangmai 5 {618}.
Add at end of section: 'ma: Distally located: Cent....Xcdo949-4V 16cM PchDv 17cM Xbcd588-4V {618}.'

Reaction to Puccinia graminis

Sr39. Add: Sr39 is closely linked with Lr35 {651}. ma: A SCAR marker was developed {9923}.
Complex genotypes:
AC Taber: Sr2, Sr9b, Sr11, Sr12 {9905}.
Pasqua: Sr5, Sr6, Sr7a, Sr9b, Sr12. Gene Lr34 acted as an enhancer of APR {9905}.

Reaction to Puccinia recondita

Lr3. ma: Co-segregation with Xmwg798-6B {9921}.
Lr28. In the 'ma' entry, change 'OPJ-02' to 'OPJ-01'.
Lr35. Insert after gene symbol: derived from Ae. speltoides {651}. Adult plant resistance {651}. Add at end of section: ma: A. SCAR marker was developed {9923}.
Lr47 {9901}. Derived from Aegilops speltoides {9901}. 7AS = Ti7AS-7S#1S-7AS·7AL {9901}. v: Pavon derivative PI 603918 {9901}. ma: Lr47 was located in the distal one-third of 7AS, 2-10cM from the centromere and within a 20-30cM segment {9901}. Complete linkage with several RFLP markers {9901}. 7A = T7AS-7S#1S·7S#1L {389}. v: CI 17882, CI 178884, CI 17885, KS 90H450 {9901}. 7AL = Ti7AS·7AL-7S#1L-7AL. v: Pavon derivative PI 603919 {9901}.

Reaction to Puccinia striiformis

Yr15. ma: Xgwm33-1B 5cM Yr15 {9904}.

Reaction to Pyrenophora tritici-repentis

2. Resistance to chlorosis induction

QTsc.ndsu-1A {9924}. Tsc1 {344}. ma: Delete last line of entry and insert: 'ma: Association with Gli-A1 {344}.'

Reaction to Schizaphis graminum

Gb5. Add: 7AL = Ti7AS·7AL-7S#1L-7AL {9901}.

Reaction to Tilletia indica Mitra

Add at bottom :
'QTL loci mapped include :
Qkb.cnl-3B [{9956}]. ma: Located in the interval XATPase-3B Xcdo1164-3B.
Qkb.cnl-5A.1 [{9956}]. ma: Located in the interval Xmwg2112-5A Xcdo20-5A.
Qkb.cnl-5A.2 [{9956}]. ma: Located in the interval Xabg391-5A Xfba351-5A.

GENETIC LINKAGES

REFERENCES

Amendments.

057. 1996 Plant Molecular Biology 32: 435-445.
158. Calonnec A & Johnson R 1998 Chromosomal location of genes for resistance to Puccinia striiformis in the wheat line TP1295 selected from the cross Soissonais-Desprez with Lemhi. European Journal of Plant Pathology 104: 835-847.
459. Proceedings of the National Academy of Sciences, USA 94: 14179-14184.
562. Update and correct: Hsam SLK, Huang XQ, Earnst F, Hartl L & Zeller FJ 1998 Theoretical and Applied Genetics 96: 1129-1134.
618. Replace with 'Yildirim A, Jones SS & Murray 1998 Mapping a gene conferring resistance to Pseudocercosporella herpotrichoides on chromosome 4V of Daspyrum villosum in a wheat background. Genome 41: 1-6.'.
727. Theoretical and Applied Genetics 96: 1104-1109.
773. Heredity 80: 83-91.
863. Ma ZQ, Saidi A, Quick JS & Lapitan NLV 1998 Genetic mapping of Russian wheat aphid resistance genes Dn2 and Dn4 in wheat. Genome 41: 303-306.
894. Marais GF, Wessels WG & Horn M 1998 Association of a stem rust resistance gene (Sr45) and two Russian wheat aphid resistance genes (Dn5 and Dn7) with mapped structural loci in wheat. South African Journal of Plants and Soil 15(2): 67-61.
1008. Revise title to 'A cytogenetic ladder map of the wheat homoeologous group-4 chromosomes.'.
1052. 1998 Theoretical and Applied Genetics 97: 535-540. Also, correct spelling of 5th author to 'Tamhankar'.
1225. 1998 Genome 41: 278-283
1231. Rogers WJ, Miller TM, Payne PI, Seekings JA, Sayers EJ, Holt LM & Law CN 1997 Introduction to bread wheat (Triticum aestivum L.) and assessment for bread-making quality of alleles from T. boeoticum Boiss. ssp. thaoudar at Glu-A1 encoding two high-molecular subunits of glutenin. Euphytica 93:19-29.
1343. 1998 A major gene for powdery mildew resistance transferred to common wheat from wild einkorn wheat. Phytopathology 88: 144-147.
1364. Singh RP, Mujeeb-Kazi A & Huerta-Espino J 1998 Lr46: a gene conferring slow-rusting resistance to leaf rust in wheat. Phytopathology 88: 890-894.
1392. Change to 'Smith JB Personal communication.'.
1425. Theoretical and Applied Genetics 97: 946-949.

New.

9901. Dubcovsky J, Lukaszewski AJ, Echaide M, Antonelli EF & Porter DR 1998 Molecular characterization of two Triticum speltoides interstitial translocations carrying leaf rust and greenbug resistance genes. Crop Science 38: 1655-1660.
9902. Kosner J & Pánková K 1998 The detection of allelic variation of the recessive Vrn loci of winter wheat. Euphytica 101: 9-16.
9903. Kato K, Miura H, Akiyama M, Kuroshima M & Sawada S 1998 RFLP mapping of the three major genes, Vrn1, Q, and B1, on the long arm of chromosome 5A of wheat. Euphytica 101: 91-95.
9904. Fahima T, Sun GL, Chaque V, Korol A, Grama A, Ronin Y & Nevo E 1997 Use of the near isogenic lines approach to identify molecular markers linked to the Yr15 stripe rust resistance gene of wheat. Israel Journal of Plant Science 45: 262.
9905. Liu JQ & Kolmer JA 1998 Genetics of stem rust resistance in wheat cultivars Pasqua and AC Taber. Phytopathology 88: 171-176.
9906. Etremova TT, Maystrenko OI, Arbuzova VS & Laikova LI 1998 Genetic analysis of glume colour in common wheat cultivars from the former USSR. Euphytica 102: 211-218.
9907. Klindworth DL, Williams ND & Joppa LR 1990 Chromosomal location of genes for supernumerary spikelet in tetraploid wheat. Genome 33: 515-520.
9908. Peng ZS, Deng CL, Yen C & Yang JL 1998 Genetic control of supernumary spikelet in common wheat line LYB. Wheat Information Service 86: 6-12.
9909. Peng Z-S, Yen C & Yang J-L 1998 Genetic control of oligo-culms in common wheat. Wheat Information Service 86: 19-24.
9910. Demeke T, Hucl P, Nair RB, Nakamura T & Chibbar R 1997 Evaluation of Canadian and other wheats for waxy proteins. Cereal Chemistry 74: 442-44.
9911. Graybosh RA, Peterson CJ, Hansen LE, Rahman S, Hill A & Skerritt JH 1998 Identification and characterization of U.S. wheats carrying null alleles at the Wx loci. Cereal Chemistry 75: 162-165.
9912. Miruta H, Tanii S, Nakamura T & Watanabe N 1994 Genetic control of amylose content in wheat endosperm starch and differential effects of three Wx genes. Theoretical and Applied Genetics 89: 276-280.
9913. Rodriguez-Quijano M, Nieto-Taldriz MT & Carrillo JM 1998 Polymorphism of waxy proteins in Iberian hexaploid wheats. Plant Breeding 117: 341-344.
9914. Urbano M, Colaprino G & Margiotta B 1996 Waxy protein variation in tetraploid and hexaploid wheats. In: C. W. Wrigley (ed), Gluten 1996 64-67.
9915. Yamamori M, Nakamura T & Kuroda A 1992 Variation in the content of starch-granule bound protein among several Japanese cultivars of common wheat (Triticum aestivum L.). Euphytica 64: 215-219.
9916. Yamamori M, Nakamura T, Endo TR & Nagamine T 1994 Waxy protein deficiency and chromosomal location of coding genes in common wheat. Theoretical and Applied Genetics 89: 179-184.
9917. Zeng M, Morris CT, Batey I & Wrigley CW 1997 Sources of variation for starch gelatinization, pasting and gelation properties in wheat. Cereal Chemistry 74: 63-71.
9918. Marais GF, Horn M & Du Toit F 1994 Intergeneric transfer (rye to wheat) of a gene(s) for Russian wheat aphid resistance. Plant Breeding 113: 265-271.
9919. Singh NK, Shepherd KW & McIntosh RA 1990 Linkage mapping of genes for resistance to leaf rust, stem rust and stripe rust and omega-secalins on the short arm of rye chromosome 1R. Theoretical and Applied Genetics 80: 609-616.
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9933. Kojima T & Ogihara Y 1998 High-resolution RFLP map of the long arm of chromosome 5A in wheat and its synteny among cereals. Genes and Genetic Systems 73: 51-58.
9934. Kojima T, Tsujimoto H & Ogihara Y 1997 High-resolution RFLP mapping of the fertility restoration (Rf3) gene against Triticum timopheevi cytoplasm located on chromosome 1BS of common wheat. Genes and Genetic Systems 72: 353-359.
9935. Kojima T, Nagaoka T, Noda K & Oghhara Y 1998 Genetic linkage map of ISSR and RAPD markers in Einkorn wheat in relation to that of RFLP markers. Theoretical and Applied Genetics 96: 37-45.
9936. Parker GD, Chalmers KJ, Rathjen AJ & Langridge P 1998 Mapping loci associated with flour colour in wheat (Triticum aestivum L.). Theoretical and Applied Genetics 97: 238-245.
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9938. Seo YW, Johnson JW & Jarret RL 1997 A molecular marker associated with the H21 Hessian fly resistance gene in wheat. Molecular Breeding 3: 177-181.
9956. Nelson JC, Autrique JE, Fuentes-Dávila G & Sorrells ME 1998 Chromosomal location of genes for resistance to Karnal bunt in wheat. Crop Science 38: 231-236.
9957. Cadalen T, Sourdille P, Charmet G, Tixier MH, Gay G, Boeuf C, Bernard S, Leroy P & Bernard M 1998 Molecular markers linked to genes affecting plant height in wheat using a doubled-haploid population. Theoretical and Applied Genetics 96: 933-940.
9958. Mingeot D & Jacquemin JM 1998 Mapping of RFLP probes characterized for their polymorphism on wheat. Theoretical and Applied Genetics (In Press).
9959. Blanco A, Bellomo MP, Cenci A, De Giovanni C, D'Ovidio R, Iacono E, Laddomada B, Pagnotta MA, Porceddu E, Sciancalepore A, Simeone R & Tanzarella OA 1998 A genetic linkage map of durum wheat. Theoretical and Applied Genetics 97: 721-728.
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9961. Bailey PC, McKibbin RS, Lenton JR, Holdsworth MJ, Flintham JE & Gale MD 1998 Genetic map locations for orthologous Vp1 genes in wheat and rice. Theoretical and Applied Genetics (In Press).
9962. Worland AJ, Korzun V, Röder MS, Ganal MW & Law CN 1998 Genetic analysis of the dwarfing gene Rht8 in wheat. Part II. The distribution and adaptive significance of allelic variants at the Rht8 locus of wheat as revealed by microsatellite screening. Theoretical and Applied Genetics 96: 1110-1120.
9963. Yildirim A, Jones SS & Murray TD 1998 Mapping a gene conferring resistance to Pseudocercosporella herpotrichoides on chromosome 4V of Dasypyrum villosum in a wheat background. Genome 41: 1-6.
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9965. Qu L-J, Foote TN, Roberts MA, Money TA, Aragón-Alcaide L, Snape JW & Moore G 1998 A simple PCR-based method for scoring the ph1b deletion in wheat. Theoretical and Applied Genetics 96: 371-375.
9966. Sourdille P, Charmet G, Trottet M, Tixier MH, Boeuf C, Nègre S, Barloy D & Bernard M 1998 Linkage between RFLP molecular markers and the dwarfing genes Rht-B1 and Rht-D1 in wheat. Hereditas 128: 41-46.
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