Heading Date QTL in Winter Wheat (Triticum aestivum L.) Coincide with Major Developmental Genes VERNALIZATION1 and PHOTOPERIOD1.

In wheat (Triticum aestivum L.), time from planting to spike emergence is influenced by genes controlling vernalization requirement and photoperiod response. Characterizing the available genetic diversity of known and novel alleles of VERNALIZATION1 (VRN1) and PHOTOPERIOD1 (PPD1) in winter wheat can inform approaches for breeding climate resilient cultivars. This study identified QTL for heading date (HD) associated with multiple VRN1 and PPD1 loci in a population developed from a cross between two early flowering winter wheat cultivars. When the population was grown in the greenhouse after partial vernalization treatment, major heading date QTLs co-located with the VRN-A1 and VRN-B1 loci. Copy number variation at the VRN-A1 locus influenced HD such that RIL having three copies required longer cold exposure to transition to flowering than RIL having two VRN-A1 copies. Sequencing vrn-B1 winter alleles of the parents revealed multiple polymorphisms in the first intron that were the basis of mapping a major HD QTL coinciding with VRN-B1. A 36 bp deletion in the first intron of VRN-B1 was associated with earlier HD after partial vernalization in lines having either two or three haploid copies of VRN-A1. The VRN1 loci interacted significantly and influenced time to heading in field experiments in Louisiana, Georgia and North Carolina. The PPD1 loci were significant determinants of heading date in the fully vernalized treatment in the greenhouse and in all field environments. Heading date QTL were associated with alleles having large deletions in the upstream regions of PPD-A1 and PPD-D1 and with copy number variants at the PPD-B1 locus. The PPD-D1 locus was determined to have the largest genetic effect, followed by PPD-A1 and PPD-B1. Our results demonstrate that VRN1 and PPD1 alleles of varying strength allow fine tuning of flowering time in diverse winter wheat growing environments.

Adsorption of Cd(II) by Mg-Al-CO3- and magnetic Fe3O4/Mg-Al-CO3-layered double hydroxides: Kinetic, isothermal, thermodynamic and mechanistic studies.

Understanding the adsorption mechanisms of metal cations on the surfaces of solids is important for determining the fate of these metals in water and wastewater treatment. The adsorption kinetic, isothermal, thermodynamic and mechanistic properties of cadmium (Cd(II)) in an aqueous solution containing Mg-Al-CO3- and magnetic Fe3O4/Mg-Al-CO3-layered double hydroxide (LDH) were studied. The results demonstrated that the adsorption kinetic and isotherm data followed the pseudo-second-order model and the Langmuir equation, respectively. The adsorption process of Cd(II) was feasible, spontaneous and endothermic in nature. X-ray diffraction (XRD) and Fourier transform infrared (FTIR) spectroscopy were used to explain the adsorption mechanisms. The characteristic XRD peaks and FTIR bands of CdCO3 emerged in the LDH spectra after Cd(II) adsorption, which indicated that the adsorption of Cd(II) by LDHs occurred mainly via CdCO3 precipitation, surface adsorption and surface complexation. Furthermore, the magnetic Fe3O4/Mg-Al-CO3-LDH can be quickly and easily separated using a magnet before and after the adsorption process.

[Molecular cytogenetic identification of Aegilops ventricosa x Aegilops cylindrica amphiploid SDAU18].

SDAU18, an amphiploid of Ae.ventricosa with Ae.cylindrica, was identified by cytological analysis, seed storage protein electrophoresis, genomic in situ hybridization (GISH) and inoculation assessment. The results are as follows: The chromosome number of root tip cells (RTCs) of SDAU18 plants varied from 52 to 56. 28 bivalents were observed in most PMCs MI of SDAU18 with 56 chromosomes, meanwhile, a few univalents, multivalents also existed in some PMCs MI, and the average chromosome configuration was 2n = 56 = 3.21 I +19.78 II, (Ring)+6.50 II (Rod)+0.01 III +0.04 IV (Ring)R+0.01 IV (Rod). There were both Ae. ventricosa-specific bands and Ae. cylindrica-specific bands in the seed storage protein electrophoretogram of SDAU18, furthermore, SDAU18 had one novel HMW-GS not found in the parents and two novel ones not found in common wheats. By labeling the total genomic DNA of Ae. ventricosa and Ae. cylindrica as probes respectively, and using that of another parent as block, GISH of RTCs spread of SDAU18 was carried out. The green hybridization signal was observed in 14 chromosomes respectively, within 56 ones in RTCs of SDAU18. SDAU18 was immune to powdery mildew and stripe rusts. SDAU18 was an amphiploid of Ae. ventricosa with Ae. cylindrica, and had very important significance in wheat breeding and genetic improvement.

[Identification of Tritielytrigia alien disomic addition line shannong 87074-519 with yellow rust resistance].

In this paper, Shannong 87074-519, a derivative of wheat-decaploid Elytrigia elongata, was identified by inoculation assessment, cytological analysis, simple sequence repeat (SSR), molecular marker technique,and genomic in situ hybridization (GISH). The results are as follows: the chromosome number of Shannong87074-519 in root tip cells was 2n=44, 22 bivalents were observed in most PMC at MI, and the average chromosome configuration was 2n=44=21.82 II+0.36 I , and the chromosome configuration (2n=43=21 II +1 I) was observed in most PMC of F1 between Shannong87074-519 and C.S. at MI. Therefore, it was an alien disomic addition line with one pair chromosome of Elytrigia elongata. Then the St total genomic DNA was labeled as probe in GISH, the green-yellow hybridization signal was observed in two intact chromosomes, indicating that Shannong87074-519 was added by one pair chromosome of St genome. The SSR-PCR technique was employed in the primer filtration, and the molecular marker BARC165 was singled out from 170 primers, which could amplify the specific molecular marker BARC165(268) of Elytrigia elongata in Shannong87074-519. Subsequently, the specific segment in Elytrigia elongata was cloned and labeled as probe in GISH of root tip cells of Shannong87074-519, the light yellow hybridization signal was observed in both chromatin at interphase and chromosome at mitotic metaphase, thus the BARC165(268) could be applied as a specific molecular marker to detect alien chromatin of Elytrigia elongata in Shannong87074-519. Because of the good agronomic characteristics, high immunity to yellow rust, and dominant new yellow rust resistant gene located at the added chromosome St, assigned as YrSt temporarily, Shannong87074-519 has very important value in wheat breeding and genetics improvement.