The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree

The mimosoid legumes are a clade of ~40 genera in the Caesalpinioideae subfamily of the Fabaceae that grow in tropical and subtropical regions. Unlike the better studied Papilionoideae, there are few genomic resources within this legume group. The tree Prosopis cineraria is native to the Near East a...

Descripción completa

Detalles Bibliográficos
Autores principales: Sudalaimuthuasari, Naganeeswaran, Ali, Rashid, Kottackal, Martin, Rafi, Mohammed, Al Nuaimi, Mariam, Kundu, Biduth, Al-Maskari, Raja Saeed, Wang, Xuewen, Mishra, Ajay Kumar, Balan, Jithin, Chaluvadi, Srinivasa R., Al Ansari, Fatima, Bennetzen, Jeffrey L., Purugganan, Michael D., Hazzouri, Khaled M., Amiri, Khaled M. A.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2022
Materias:
Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9369113/
https://www.ncbi.nlm.nih.gov/pubmed/35955640
http://dx.doi.org/10.3390/ijms23158503
_version_ 1784766358600286208
author Sudalaimuthuasari, Naganeeswaran
Ali, Rashid
Kottackal, Martin
Rafi, Mohammed
Al Nuaimi, Mariam
Kundu, Biduth
Al-Maskari, Raja Saeed
Wang, Xuewen
Mishra, Ajay Kumar
Balan, Jithin
Chaluvadi, Srinivasa R.
Al Ansari, Fatima
Bennetzen, Jeffrey L.
Purugganan, Michael D.
Hazzouri, Khaled M.
Amiri, Khaled M. A.
author_facet Sudalaimuthuasari, Naganeeswaran
Ali, Rashid
Kottackal, Martin
Rafi, Mohammed
Al Nuaimi, Mariam
Kundu, Biduth
Al-Maskari, Raja Saeed
Wang, Xuewen
Mishra, Ajay Kumar
Balan, Jithin
Chaluvadi, Srinivasa R.
Al Ansari, Fatima
Bennetzen, Jeffrey L.
Purugganan, Michael D.
Hazzouri, Khaled M.
Amiri, Khaled M. A.
author_sort Sudalaimuthuasari, Naganeeswaran
collection PubMed
description The mimosoid legumes are a clade of ~40 genera in the Caesalpinioideae subfamily of the Fabaceae that grow in tropical and subtropical regions. Unlike the better studied Papilionoideae, there are few genomic resources within this legume group. The tree Prosopis cineraria is native to the Near East and Indian subcontinent, where it thrives in very hot desert environments. To develop a tool to better understand desert plant adaptation mechanisms, we sequenced the P. cineraria genome to near-chromosomal assembly, with a total sequence length of ~691 Mb. We predicted 77,579 gene models (76,554 CDS, 361 rRNAs and 664 tRNAs) from the assembled genome, among them 55,325 (~72%) protein-coding genes that were functionally annotated. This genome was found to consist of over 58% repeat sequences, primarily long terminal repeats (LTR-)-retrotransposons. We find an expansion of terpenoid metabolism genes in P. cineraria and its relative Prosopis alba, but not in other legumes. We also observed an amplification of NBS-LRR disease-resistance genes correlated with LTR-associated retrotransposition, and identified 410 retrogenes with an active burst of chimeric retrogene creation that approximately occurred at the same time of divergence of P. cineraria from a common lineage with P. alba~23 Mya. These retrogenes include many biotic defense responses and abiotic stress stimulus responses, as well as the early Nodulin 93 gene. Nodulin 93 gene amplification is consistent with an adaptive response of the species to the low nitrogen in arid desert soil. Consistent with these results, our differentially expressed genes show a tissue specific expression of isoprenoid pathways in shoots, but not in roots, as well as important genes involved in abiotic salt stress in both tissues. Overall, the genome sequence of P. cineraria enriches our understanding of the genomic mechanisms of its disease resistance and abiotic stress tolerance. Thus, it is a very important step in crop and legume improvement.
format Online
Article
Text
id pubmed-9369113
institution National Center for Biotechnology Information
language English
publishDate 2022
publisher MDPI
record_format MEDLINE/PubMed
spelling pubmed-93691132022-08-12 The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree Sudalaimuthuasari, Naganeeswaran Ali, Rashid Kottackal, Martin Rafi, Mohammed Al Nuaimi, Mariam Kundu, Biduth Al-Maskari, Raja Saeed Wang, Xuewen Mishra, Ajay Kumar Balan, Jithin Chaluvadi, Srinivasa R. Al Ansari, Fatima Bennetzen, Jeffrey L. Purugganan, Michael D. Hazzouri, Khaled M. Amiri, Khaled M. A. Int J Mol Sci Article The mimosoid legumes are a clade of ~40 genera in the Caesalpinioideae subfamily of the Fabaceae that grow in tropical and subtropical regions. Unlike the better studied Papilionoideae, there are few genomic resources within this legume group. The tree Prosopis cineraria is native to the Near East and Indian subcontinent, where it thrives in very hot desert environments. To develop a tool to better understand desert plant adaptation mechanisms, we sequenced the P. cineraria genome to near-chromosomal assembly, with a total sequence length of ~691 Mb. We predicted 77,579 gene models (76,554 CDS, 361 rRNAs and 664 tRNAs) from the assembled genome, among them 55,325 (~72%) protein-coding genes that were functionally annotated. This genome was found to consist of over 58% repeat sequences, primarily long terminal repeats (LTR-)-retrotransposons. We find an expansion of terpenoid metabolism genes in P. cineraria and its relative Prosopis alba, but not in other legumes. We also observed an amplification of NBS-LRR disease-resistance genes correlated with LTR-associated retrotransposition, and identified 410 retrogenes with an active burst of chimeric retrogene creation that approximately occurred at the same time of divergence of P. cineraria from a common lineage with P. alba~23 Mya. These retrogenes include many biotic defense responses and abiotic stress stimulus responses, as well as the early Nodulin 93 gene. Nodulin 93 gene amplification is consistent with an adaptive response of the species to the low nitrogen in arid desert soil. Consistent with these results, our differentially expressed genes show a tissue specific expression of isoprenoid pathways in shoots, but not in roots, as well as important genes involved in abiotic salt stress in both tissues. Overall, the genome sequence of P. cineraria enriches our understanding of the genomic mechanisms of its disease resistance and abiotic stress tolerance. Thus, it is a very important step in crop and legume improvement. MDPI 2022-07-31 /pmc/articles/PMC9369113/ /pubmed/35955640 http://dx.doi.org/10.3390/ijms23158503 Text en © 2022 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Sudalaimuthuasari, Naganeeswaran
Ali, Rashid
Kottackal, Martin
Rafi, Mohammed
Al Nuaimi, Mariam
Kundu, Biduth
Al-Maskari, Raja Saeed
Wang, Xuewen
Mishra, Ajay Kumar
Balan, Jithin
Chaluvadi, Srinivasa R.
Al Ansari, Fatima
Bennetzen, Jeffrey L.
Purugganan, Michael D.
Hazzouri, Khaled M.
Amiri, Khaled M. A.
The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title_full The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title_fullStr The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title_full_unstemmed The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title_short The Genome of the Mimosoid Legume Prosopis cineraria, a Desert Tree
title_sort genome of the mimosoid legume prosopis cineraria, a desert tree
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9369113/
https://www.ncbi.nlm.nih.gov/pubmed/35955640
http://dx.doi.org/10.3390/ijms23158503
work_keys_str_mv AT sudalaimuthuasarinaganeeswaran thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alirashid thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT kottackalmartin thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT rafimohammed thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alnuaimimariam thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT kundubiduth thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT almaskarirajasaeed thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT wangxuewen thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT mishraajaykumar thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT balanjithin thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT chaluvadisrinivasar thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alansarifatima thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT bennetzenjeffreyl thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT puruggananmichaeld thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT hazzourikhaledm thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT amirikhaledma thegenomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT sudalaimuthuasarinaganeeswaran genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alirashid genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT kottackalmartin genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT rafimohammed genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alnuaimimariam genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT kundubiduth genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT almaskarirajasaeed genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT wangxuewen genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT mishraajaykumar genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT balanjithin genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT chaluvadisrinivasar genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT alansarifatima genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT bennetzenjeffreyl genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT puruggananmichaeld genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT hazzourikhaledm genomeofthemimosoidlegumeprosopiscinerariaadeserttree
AT amirikhaledma genomeofthemimosoidlegumeprosopiscinerariaadeserttree

Ejemplares similares