Grzegorz Bartoszewski scite author profile

Cucumber (Cucumis sativus L.), a widely cultivated crop, has originated from Eastern Himalayas and secondary domestication regions includes highly divergent climate conditions e.g. temperate and subtropical. We wanted to uncover adaptive genome differences between the cucumber cultivars and what sort of evolutionary molecular mechanisms regulate genetic adaptation of plants to different ecosystems and organism biodiversity. Here we present the draft genome sequence of the Cucumis sativus genome of the North-European Borszczagowski cultivar (line B10) and comparative genomics studies with the known genomes of: C. sativus (Chinese cultivar – Chinese Long (line 9930)), Arabidopsis thaliana, Populus trichocarpa and Oryza sativa. Cucumber genomes show extensive chromosomal rearrangements, distinct differences in quantity of the particular genes (e.g. involved in photosynthesis, respiration, sugar metabolism, chlorophyll degradation, regulation of gene expression, photooxidative stress tolerance, higher non-optimal temperatures tolerance and ammonium ion assimilation) as well as in distributions of abscisic acid-, dehydration- and ethylene-responsive cis-regulatory elements (CREs) in promoters of orthologous group of genes, which lead to the specific adaptation features. Abscisic acid treatment of non-acclimated Arabidopsis and C. sativus seedlings induced moderate freezing tolerance in Arabidopsis but not in C. sativus. This experiment together with analysis of abscisic acid-specific CRE distributions give a clue why C. sativus is much more susceptible to moderate freezing stresses than A. thaliana. Comparative analysis of all the five genomes showed that, each species and/or cultivars has a specific profile of CRE content in promoters of orthologous genes. Our results constitute the substantial and original resource for the basic and applied research on environmental adaptations of plants, which could facilitate creation of new crops with improved growth and yield in divergent conditions.

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Mosaic (MSC) cucumbers regenerated from independent cell cultures possess different mitochondrial rearrangements

Bartoszewski

Malepszy²,

Havey

2004

Current Genetics

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Passage of the highly inbred cucumber ( Cucumis sativus L.) line B through cell culture produces progenies with paternally transmitted, mosaic (MSC) phenotypes. Because the mitochondrial genome of cucumber shows paternal transmission, we evaluated for structural polymorphisms by hybridizing cosmids spanning the entire mitochondrial genome of Arabidopsis thaliana L. to DNA-gel blots of four independently generated MSC and four wild-type cucumbers. Polymorphisms were identified by cosmids carrying rrn18, nad5-exon2, rpl5, and the previously described JLV5 deletion. Polymorphisms revealed by rrn18 and nad5-exon2 were due to one rearrangement bringing together these two coding regions. The polymorphism revealed by rpl5 was unique to MSC16 and was due to rearrangement(s) placing the rpl5 region next to the forward junction of the JLV5 deletion. The rearrangement near rpl5 existed as a sublimon in wild-type inbred B, but was not detected in the cultivar Calypso. Although RNA-gel blots revealed reduced transcription of rpl5 in MSC16 relative to wild-type cucumber, Western analyses revealed no differences for the RPL5 protein and the genetic basis of the MSC16 phenotype remains enigmatic. We evaluated 17 MSC and wild-type lines regenerated from independent cell-culture experiments for these structural polymorphisms and identified eight different patterns, indicating that the passage of cucumber through cell culture may be a unique mechanism to induce or select for novel rearrangements affecting mitochondrial gene expression.

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A major deletion in the cucumber mitochondrial genome sorts with the MSC phenotype

et al. 2001

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The cucumber mitochondrial genome is unique because of its large size, paternal transmission, and the existence of a paternally transmitted mosaic (MSC) phenotype spontaneously appearing after independent tissue culture experiments. Transmission studies eliminated paternal imprinting as the genetic basis for the MSC phenotype. We identified a 13 kb region (JLV5-DEL) in the wild-type mitochondrial genome that was absent from three MSC lines. This deleted region was paternally transmitted with the MSC phenotype through the F3 and test-cross generations. Southern hybridizations and PCR amplifications using primers within the JLV5 region revealed that rare wild-type sorters possessed the wild-type region. MSC plants possess the wild-type region at levels (approximately 0.002) below detection by standard PCR reactions and Southern hybridizations, using genomic DNA. Sequence analysis of the wild-type contig revealed no homologies to mitochondrial genes and no open reading frames within JLV5-DEL. PCR amplifications across JLV5-DEL using MSC mtDNA revealed that the loss of this region was not a simple deletion and may be associated with a rearrangement. Because no genic regions were identified within the wild-type JLV5 region, the specific lesion conditioning the MSC phenotype may be associated with the putative rearrangement or another mutation that occurred during tissue culture or exists substoichiometrically in the parental line and is transmitted together with JLV5 within the same mitochondrion.

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