Characterization of terminal flowering cowpea (Vigna unguiculata (L.) Walp.) mutants obtained by induced mutagenesis digs out the loss-of-function of phosphatidylethanolamine-binding protein.

Cowpea (Vigna unguiculata (L.) Walp) is one of the major food legume crops grown extensively in arid and semi-arid regions of the world. The determinate habit of cowpea has many advantages over the indeterminate and is well adapted to modern farming systems. Mutation breeding is an active research area to develop the determinate habit of cowpea. The present study aimed to develop new determinate habit mutants with terminal flowering (TFL) in locally well-adapted genetic backgrounds. Consequently, the seeds of popular cowpea cv P152 were irradiated with doses of gamma rays (200, 250, and, 300 Gy), and the M1 populations were grown. The M2 populations were produced from the M1 progenies and selected determinate mutants (TFLCM-1 and TFLCM-2) from the M2 generation (200 Gy) were forwarded up to the M5 generation to characterize the mutants and simultaneously they were crossed with P152 to develop a MutMap population. In the M5 generation, determinate mutants (80-81 days) were characterized by evaluating the TFL growth habit, longer peduncles (30.75-31.45 cm), erect pods (160°- 200°), number of pods per cluster (4-5 nos.), and early maturity. Further, sequencing analysis of the VuTFL1 gene in the determinate mutants and MutMap population revealed a single nucleotide transversion (A-T at 1196 bp) in the fourth exon and asparagine (N) to tyrosine (Y) amino acid change at the 143rd position of phosphatidylethanolamine-binding protein (PEBP). Notably, the loss of function PEPB with a higher confidence level modification of anti-parallel beta-sheets and destabilization of the protein secondary structure was observed in the mutant lines. Quantitative real-time PCR (qRT-PCR) analysis showed that the VuTFL1 gene was downregulated at the flowering stage in TFL mutants. Collectively, the insights garnered from this study affirm the effectiveness of induced mutation in modifying the plant's ideotype. The TFL mutants developed during this investigation have the potential to serve as a valuable resource for fostering determinate traits in future cowpea breeding programs and pave the way for mechanical harvesting.

Effectiveness and efficiency of electron beam in comparison with gamma rays and ethyl methane sulfonate mutagens in cowpea.

Cowpea is the poor man's crop that lacks variability due to its autogamous nature. Induced mutation serves as a potential source in the induction of variability in crops. On the other hand, the effectiveness and efficiency of mutagens will vary between species and even varieties. In the present study, a novel mutagen electron beam was used in cowpea for the first time along with commonly used mutagens gamma rays (physical) and ethyl methanesulfonate (chemical). The biological damages on eight quantitative characters in M1 generation and chlorophyll mutants in M2 generation were recorded. Two popular varieties viz., P 152 and VBN 1 constituted as the biological material of study. The rate of reduction in biological damage on quantitative characters was directly proportional to the dose of mutagen irrespective of the varieties and mutagens used. Physical mutagens showed the highest biological damage (EB- 37.5% and G- 37.3% overall reduction from control) than chemical mutagen (EMS- 30.4%). Comparing the physical mutagens at similar doses, 200 Gy or 300 Gy of electron beam showed more biological damage than 200 Gy or 300 Gy of gamma rays. Eleven different types of chlorophyll mutants were identified in the M2 generation. Xantha is the most occurred chlorophyll mutants (44.44%), while aurea and yellow viridis have least occurred mutants. Chemical mutagen (EMS) is considered to be the most effective (6.47%) and efficient mutagen (27.09%) based on the chlorophyll mutants and it was followed by an electron beam and gamma rays. Among the physical mutagens, electron beam showed the highest biological damage (37.50% overall reduction from control) and higher effectiveness and efficiency (3.80% and 23.38%) compared to gamma rays (1.87% and 13.38%). Hence, the electron beam can also be used as an effective mutagen in creating variation in cowpea and other crops as it is highly effective, cost less and safe mutagen.