A universal predictive and mechanistic urinary peptide signature in acute kidney injury.

BACKGROUND: The delayed diagnosis of acute kidney injury (AKI) episodes and the lack of specificity of current single AKI biomarkers hamper its management. Urinary peptidome analysis may help to identify early molecular changes in AKI and grasp its complexity to identify potential targetable molecular pathways. METHODS: In derivation and validation cohorts totalizing 1170 major cardiac bypass surgery patients and in an external cohort of 1569 intensive care unit (ICU) patients, a peptide-based score predictive of AKI (7-day KDIGO classification) was developed, validated, and compared to the reference biomarker urinary NGAL and NephroCheck and clinical scores. RESULTS: A set of 204 urinary peptides derived from 48 proteins related to hemolysis, inflammation, immune cells trafficking, innate immunity, and cell growth and survival was identified and validated for the early discrimination (< 4 h) of patients according to their risk to develop AKI (OR 6.13 [3.96-9.59], p < 0.001) outperforming reference biomarkers (urinary NGAL and [IGFBP7].[TIMP2] product) and clinical scores. In an external cohort of 1569 ICU patients, performances of the signature were similar (OR 5.92 [4.73-7.45], p < 0.001), and it was also associated with the in-hospital mortality (OR 2.62 [2.05-3.38], p < 0.001). CONCLUSIONS: An overarching AKI physiopathology-driven urinary peptide signature shows significant promise for identifying, at an early stage, patients who will progress to AKI and thus to develop tailored treatments for this frequent and life-threatening condition. Performance of the urine peptide signature is as high as or higher than that of single biomarkers but adds mechanistic information that may help to discriminate sub-phenotypes of AKI offering new therapeutic avenues.

Catastrophic Unbalanced Genome Rearrangements Cause Somatic Loss of Berry Color in Grapevine.

Grape (Vitis vinifera) color somatic variants that can be used to develop new grapevine cultivars occasionally appear associated with deletion events of uncertain origin. To understand the mutational mechanisms generating somatic structural variation in grapevine, we compared the Tempranillo Blanco (TB) white berry somatic variant with its black berry ancestor, Tempranillo Tinto. Whole-genome sequencing uncovered a catastrophic genome rearrangement in TB that caused the hemizygous deletion of 313 genes, including the loss of the functional copy for the MYB transcription factors required for anthocyanin pigmentation in the berry skin. Loss of heterozygosity and decreased copy number delimited interspersed monosomic and disomic regions in the right arm of linkage groups 2 and 5. At least 11 validated clustered breakpoints involving intrachromosomal and interchromosomal translocations between three linkage groups flanked the deleted fragments, which, according to segregation analyses, are phased in a single copy of each of the affected chromosomes. These hallmarks, along with the lack of homology between breakpoint joins and the randomness of the order and orientation of the rearranged fragments, are all consistent with a chromothripsis-like pattern generated after chromosome breakage and illegitimate rejoining. This unbalanced genome reshuffling has additional consequences in reproductive development. In TB, lack of sexual transmission of rearranged chromosomes associates with low gamete viability, which compromises fruit set and decreases fruit production. Our findings show that catastrophic genome rearrangements arise spontaneously and stabilize during plant somatic growth. These dramatic rearrangements generate new interesting phenotypes that can be selected for the improvement of vegetatively propagated plant species.

Identification of Two New Mechanisms That Regulate Fruit Growth by Cell Expansion in Tomato.

Key mechanisms controlling fruit weight and shape at the levels of meristem, ovary or very young fruit have already been identified using natural tomato diversity. We reasoned that new developmental modules prominent at later stages of fruit growth could be discovered by using new genetic and phenotypic diversity generated by saturated mutagenesis. Twelve fruit weight and tissue morphology mutants likely affected in late fruit growth were selected among thousands of fruit size and shape EMS mutants available in our tomato EMS mutant collection. Their thorough characterization at organ, tissue and cellular levels revealed two major clusters controlling fruit growth and tissue morphogenesis either through (i) the growth of all fruit tissues through isotropic cell expansion or (ii) only the growth of the pericarp through anisotropic cell expansion. These likely correspond to new cell expansion modules controlling fruit growth and tissue morphogenesis in tomato. Our study therefore opens the way for the identification of new gene regulatory networks controlling tomato fruit growth and morphology.

Rapid identification of causal mutations in tomato EMS populations via mapping-by-sequencing.

The tomato is the model species of choice for fleshy fruit development and for the Solanaceae family. Ethyl methanesulfonate (EMS) mutants of tomato have already proven their utility for analysis of gene function in plants, leading to improved breeding stocks and superior tomato varieties. However, until recently, the identification of causal mutations that underlie particular phenotypes has been a very lengthy task that many laboratories could not afford because of spatial and technical limitations. Here, we describe a simple protocol for identifying causal mutations in tomato using a mapping-by-sequencing strategy. Plants displaying phenotypes of interest are first isolated by screening an EMS mutant collection generated in the miniature cultivar Micro-Tom. A recombinant F2 population is then produced by crossing the mutant with a wild-type (WT; non-mutagenized) genotype, and F2 segregants displaying the same phenotype are subsequently pooled. Finally, whole-genome sequencing and analysis of allele distributions in the pools allow for the identification of the causal mutation. The whole process, from the isolation of the tomato mutant to the identification of the causal mutation, takes 6-12 months. This strategy overcomes many previous limitations, is simple to use and can be applied in most laboratories with limited facilities for plant culture and genotyping.

Culture of the Tomato Micro-Tom Cultivar in Greenhouse.

Micro-Tom tomato cultivar is particularly adapted to the development of genomic approaches in tomato. Here, we describe the culture of this plant in greenhouse, including climate regulation, seed sowing and watering, vegetative development, plant maintenance, including treatment of phytosanitary problems, and reproductive development.

Haplotype diversity of VvTFL1A gene and association with cluster traits in grapevine (V. vinifera).

BACKGROUND: Interaction between TERMINAL FLOWER 1 (TFL1) and LEAFY (LFY) seem to determine the inflorescence architecture in Arabidopsis. In a parallel way, overexpression of VvTFL1A, a grapevine TFL1 homolog, causes delayed flowering and production of a ramose cluster in the reiterated reproductive meristem (RRM) somatic variant of cultivar Carignan. To analyze the possible contribution of this gene to cluster phenotypic variation in a diversity panel of cultivated grapevine (Vitis vinifera L. subsp. vinifera) its nucleotide diversity was characterized and association analyses among detected sequence polymorphisms and phenology and cluster traits was carried out. RESULTS: A total of 3.6 kb of the VvTFL1A gene, including its promoter, was sequenced in a core collection of 140 individuals designed to maximize phenotypic variation at agronomical relevant traits. Nucleotide variation for VvTFL1A within this collection was higher in the promoter and intron sequences than in the exon regions; where few polymorphisms were located in agreement with a high conservation of coding sequence. Characterization of the VvTFL1A haplotype network identified three major haplogroups, consistent with the geographic origins and the use of the cultivars that could correspond to three major ancestral alleles or evolutionary branches, based on the existence of mutations in linkage disequilibrium. Genetic association studies with cluster traits revealed the presence of major INDEL polymorphisms, explaining 16%, 13% and 25% of flowering time, cluster width and berry weight, respectively, and also structuring the three haplogroups. CONCLUSIONS: At least three major VvTFL1A haplogroups are present in cultivated grapevines, which are defined by the presence of three main polymorphism LD blocks and associated to characteristic phenotypic values for flowering time, cluster width and berry size. Phenotypic differences between haplogroups are consistent with differences observed between Eastern and Western grapevine cultivars and could result from the use of different genetic pools in the domestication process as well as different selection pressures on the development of table and wine cultivars, respectively. Altogether, these results are coherent with previous classifications of grapevine phenotypic diversity mainly based on cluster and berry morphotypes as well as with recent results on the structure of genetic diversity in cultivated grapevine.

Mis-expression of a PISTILLATA-like MADS box gene prevents fruit development in grapevine.

The FLESHLESS BERRY (Flb) somatic variant identified in the grapevine cultivar Ugni Blanc develops grape berries without flesh, suggesting a role for the altered gene in differentiation of flesh cells. Here we describe identification of the molecular defect responsible for this phenotype. Using a combination of genetic and transcriptomic approaches, we detected the insertion of a miniature inverted-repeat transposable element in the promoter region of the PISTILLATA-like (VvPI) gene, the grapevine homologue of Arabidopsis PISTILLATA. The transposon insertion causes specific ectopic expression of the corresponding VvPI allele during early fruit development, causing expression of genes specific for petal and stamen development within the fruit. A causal relationship between the insertion and the phenotype was demonstrated by phenotypic and molecular analyses of somatic revertants showing that ectopic expression and mutant phenotype were always linked to the presence of the transposon insertion. The various phenotypic effects of the flb mutation on ovary morphology, fruit set and fruit development, depending on the cell lineage affected, are presented for each phenotype, offering new insights into floral and fleshly fruit development. The results highlight the importance of VvPI repression after fertilization to achieve normal fleshy fruit development, and the complex genetic, genomic and cellular interactions required for the flower to fruit transition in grapevine.

Transposon-induced gene activation as a mechanism generating cluster shape somatic variation in grapevine.

We have characterized the genetic and molecular origin of the reiterated reproductive meristem (RRM) somatic variant phenotype of grapevine cultivar Carignan. Here, we show that the extreme cluster proliferation and delayed anthesis observed in this somatic variant is caused by a single dominant mutation. Transcriptional profiling of Carignan and RRM plants during early stages of inflorescence development demonstrated the overexpression of a few regulatory genes, including VvTFL1A, a close TFL1 Arabidopsis homolog, in RRM inflorescences. Genetic and molecular analyses correlated the insertion of a class-II transposable element, Hatvine1-rrm, in the VvTFL1A promoter, with upregulation of the corresponding VvTFL1A allele in reproductive and vegetative organs of the shoot apex. These results suggest a role for this TFL1 grapevine homolog in the determination of inflorescence structure, with a critical effect on the size and branching pattern of grapevine fruit clusters. Our results demonstrate the existence of spontaneous cis-activation processes caused by class-II transposable elements in grapevine plants, and point to their possible role as a mechanism to generate somatic cell variation in perennial plants. This mechanism is expected to generate dominant phenotypes in chimeric sectors that can be readily exposed to natural selection.

Characterization of Vitis vinifera L. somatic variants exhibiting abnormal flower development patterns.

Mutants have proven to be a key resource for functional genomic studies in model annual plant species. In perennial plant species where mutants are difficult to generate and to screen, spontaneous somatic variants represent a unique resource to understand the genetic control of complex developmental patterns. The morphological and histological characterization of six Vitis vinifera L. somatic variants that display four different abnormal phenotypes of flower development are described here. A phenotype of reiterated reproductive meristems (RRM), with both flower and petal reiteration, was observed in a somatic variant of the cultivar Carignan. An abnormal development of reproductive organs was displayed by the unfused carpels (UFC) somatic variant of cv. Bouchalès, while a somatic variant of cv. Mourvèdre named carpel-less (CLS) developed abnormal ovules in the absence of carpels. Finally, three independent somatic variants in cvs Gamay, Morrastel, and Pinot displayed a phenotype of multiple perianth whorls (MPW). Gene expression studies showed that the expression profiles of VvMADS-box 1, 2, and 3 (putative orthologues of Arabidopsis flowering genes AG, SEP, and AGL13), were altered during grapevine flower development in the somatic variants, whereas the corresponding original cultivars displayed similar VvMADS-box gene expression profiles. Phenotypic and molecular characterization of these variants allowed the development of hypotheses on genetic functions that might be altered in most of the variants in light of the current ABCDE flower model.

Identification of genes associated with flesh morphogenesis during grapevine fruit development.

Fruit morphogenesis is a process unique to the angiosperms, and yet little is known about its developmental control. Following fertilization, fruits typically undergo a dramatic enlargement that is accompanied by differentiation of numerous distinct cell types. To identify genes putatively involved in the early development of grapevine fruit, we used the fleshless berry mutant (Vitis vinifera L. cv Ugni Blanc) that has dramatically reduced fruit size due to a lack of pericarp development. Using oligo-specific arrays, 53 and 50 genes were identified as being down- and up-regulated, respectively, in the mutant. In parallel, Suppression Subtractive Hybridization performed between the mutant and the wild type (WT) allowed the identification of new transcripts differentially expressed during the first stages of mutant and WT pericarp development. From this data, the picture emerged that the mutation promotes the expression of several genes related to ripening and/or to stress and impairs the expression of several regulatory genes. Among those, five genes encoding proteins previously reported to be associated with, or involved in, developmental processes in other species (a specific tissue protein 2, ATHB13, a BURP domain protein, PISTILLATA, and YABBY2), were identified and investigated further using real-time PCR and in situ hybridization. Expression in the pericarp was confirmed, specific spatial and/or temporal patterns were detected and differences were observed between the WT and the mutant during fruit development. Expression of these genes appeared to be affected during young fruit development in the mutant, suggesting that they may play a role in grape berry morphogenesis.

The grapevine fleshless berry mutation. A unique genotype to investigate differences between fleshy and nonfleshy fruit.

In flowering plants, fruit morphogenesis is a distinct process following fertilization resulting in the formation of a specialized organ associated with seeds. Despite large variations in types and shapes among species, fleshy fruits share common characteristics to promote seed dispersal by animals such as organ growth and metabolite accumulation to attract animal feeding. The molecular biology of fruit ripening has received considerable attention, but little is known about the determinism of early fruit morphogenesis and why some fruits are fleshy while others lack flesh. We have identified in grapevine (Vitis vinifera) a mutation we have named fleshless berry (flb) that reduces by 20 times the weight of the pericarp at ripening without any effect on fertility or seed size and number. The flb mutation strongly impaired division and differentiation of the most vacuolated cells in the inner mesocarp. The timing of ripening was not altered by the mutation although the accumulation of malic acid in the green stage was noticeably reduced while sucrose content (instead of hexoses) increased during ripening. The mutation segregates as a single dominant locus. These results indicate that the Flb- mutant is suitable material to advance our understanding of the genetic and developmental processes involved in the differentiation of an ovary into a fruit.

VvMADS9, a class B MADS-box gene involved in grapevine flowering, shows different expression patterns in mutants with abnormal petal and stamen structures.

VvMADS9, a MADS-box gene, from grapevine (Vitis vinifera L.) cultivar Cabernet Sauvignon has been isolated and its expression pattern studied in wild type Cabernet Sauvignon, Mourvèdre, and Bouchalès cultivars and mutants of the latter two genotypes showing abnormal petal / stamen structures. Sequence analysis showed that VvMADS9 was highly similar to PISTILLATA (PI), the class B gene that specifies the identity of petals and stamens in Arabidopsis. The temporal expression pattern of VvMADS9 studied through real-time PCR revealed that its expression was specific to flower development. The low levels of expression in the Mourvèdre mutant and the skewed expression pattern in the Bouchalès mutant as compared to their wild type counterparts suggested that VvMADS9 is involved in normal formation of petals and stamens. Through in situ hybridisation, expression of VvMADS9 was detected in stamens and weak expression on the basal regions of the petals. This suggested a possible role for VvMADS9 in specifying stamen and petal organ identity in grapevine similar to Class B genes in other species. All evidence thus pointed to the conclusion that VvMADS9 is an orthologue of PISTILLATA in grapevine.