Strategies for selecting mutation sites for methionine enhancement in the bean seed storage protein phaseolin

The complete three-dimensional structure of the bean seed storage protein phaseolin was generated from -carbon coordinates by using molecular mechanic calculations. This structure was used as a template to simulate modifications aimed at increasing the methionine content of phaseolin. A hydrophilic, methionine-rich looping insert sequence was designed. Simulated mutagenesis shows that the insert might be accommodated in turn and loop regions of the protein, but not within an -helix. Methionine content was also increased by the replacement of hydrophobic amino acids with methionine in the central core -barrels of the phaseolin protein. Calculations indicated that methionine can effectively replace conserved or variant leucine, isolecuine, and valine residues. However, alanine residues were much more sensitive to substitution, and demonstrated high variability in the effects of methionine replacement. Introduction of multiple substitutions in the barrel interior demonstrated that the replaced residues could interact favorably to relieve local perturbations caused by individual substitutions. Molecular dynamics simulations were also utilized to study the structural organization of phaseolin. The calculations indicate that there are extensive packing interactions between the major domains of phaseolin, which have important implications for protein folding and stability. Since the proposed mutant proteins can be produced and studied, the results presented here provide an ideal test to determine if there is a correlation between the effects obtained by computer simulation and the effects of the mutations on the protein structure expressedin vivo.     

Chloroplast DNA variation and phylogeny of theRanunculaceae

Restriction site mapping of chloroplast DNA from 31 species representing 26 genera of theRanunculaceae was performed using eleven restriction endonucleases. The chloroplast genome varies in length from approximately 152 to 160 kb. Length variants are frequent in theRanunculaceae and range from usually less than 300 bp to rarely 1.5 kb. The inverted repeat is extended into the large single copy (LSC) region by 4–4.5 kb inAnemone, Clematis, Clematopsis, Hepatica, Knowltonia, andPulsatilla. Several inversions are present in the LSC-region of the cpDNA in all these genera and inAdonis. The frequency of restriction site mutations varies within the chloroplast genome in theRanunculaceae between 4 and 32 mutations per kilobase, and is lowest in the inverted repeat and the regions containing the ATPase-genes and the genespsaA, psaB, psbA, rpoB, andrbcL. A total of 547 phylogenetically informative restriction sites was utilized in cladistic analyses of the family using Wagner, Dollo, and weighted parsimony. These three parsimony analyses result in different tree topologies. Four, six, and one equally most parsimonious trees were obtained with Wagner, Dollo, and weighted parsimony, respectively. The amount of support for the monophyletic groups was evaluated using bootstrapping and decay analysis. All three parsimony methods suggest thatHydrastis is the sister group to the remainder of theRanunculaceae, and that theAnemone-Clematis group, which shares several derived cpDNA rearrangements, is monophyletic. Only a few of the traditional groups in theRanunculaceae are supported by cpDNA restriction side data. Only Dollo parsimony provides support for the hypothesis thatThalictroideae andRanunculoideae are monophyletic.     

Specificity and regulation of the mutator transposable element system in maize

The Mutator transposable element system is exceptional in many of its basic attributes. The high frequency and low specificity of mutant induction are both unusual and useful characteristics of the Mutator system. Other basic features are at least equally fascinating: the existence of multiple Mu element subfamilies with apparently unrelated internal sequences; the lack of correlation between Mu element transposition and excision; the complex inheritance of Mutator activity; the tight developmental regulation of Afufaror‐conditioned events; and the coordinated processes of element modification/inactivation, to name a few.

Molecular and genetic studies over the last 10 years have begun to explain many of these interesting properties and have uncovered new mysteries of Mutator biology. Both positive and negative regulators of the system have been identified and characterized to varying degrees. Insertion specificity has been observed at several levels. Recent accomplishments include the isolation of an autonomous Mu element and the discovery of maize lines with altered developmental regulation of Mutator‐derived mutability. This review defines the Mutator system, describes the status of current experimentation in the Mutator field, proposes models that may explain some aspects of Mutator behavior, and details future studies that will help elucidate the nature of the Mutator phenomenon.     

Pan-Cancer analyses of Necroptosis-Related genes as a potential target to predict immunotherapeutic outcome

Necroptosis is a unique programmed death mechanism of necrotic cells. However, its role and specific mechanism in cancer remain unclear, and a systematic pan-cancer analysis of necroptosis is yet to be conducted. Thus, we performed a specific pan-cancer analysis using The Cancer Genome Atlas and Genotype-Tissue Expression databases to analyse necroptosis expression in terms of cancer prognosis, DNA methylation status, tumour mutative burden, microsatellite instability, immune cell infiltration in different types of cancer and molecular mechanisms. For the first time, we explored the correlation between necroptosis and immunotherapy prognosis. Thus, our study provides a relatively comprehensive understanding of the carcinogenicity of necroptosis in different types of cancer. It is suggested that necroptosis can be used to evaluate the sensitivity of different patients to immunotherapy and may become a potential target for tumour immunotherapy.     

3. Genetic conservation in seed banks

The safest and most economical and convenient way of preserving the genetic resources of the majority of crop plants is by long-term seed storage. The technology is well developed, but recent research resulting from a greater understanding of behaviour at very low water potentials is leading to further improvements     

DEVELOPMENTAL MUTANTS OF VOLVOX: DOES MUTATION RECREATE THE PATTERNS OF PHYLOGENETIC DIVERSITY?

The nature of the variation which is created by mutation can show how the direction of evolution is constrained by internal biases arising from development and pre-existing design. We have attempted to quantify these biases by measuring eight life history characters in developmental mutants of Volvox carteri. Most of the mutants in our sample were inferior to the wild type, but deviated by less than tenfold from the wild-type mean. Characters differed in mutability, suggesting different levels of canalisation. Most correlations between life history characters among strains were positive, but there was a significant negative correlation between the size and the number of reproductive cells, suggesting an upper limit to the total quantity of germ produced by individuals. The most extreme phenotypes in our sample were very vigorous, showing that not all mutations of large effect are unconditionally deleterious. We investigated the effect of developmental constraints on the course of evolution by comparing the variance and covariance patterns among mutant strains with those among species in the family Volvocaceae. A close correspondence between patterns at these two levels would suggest that pre-existing design has a strong influence on evolution, while little or no correspondence shows the action of selection. The variance generated by mutation was equal to that generated by speciation in the family Volvocaceae, the genus Volvox, or the section Merillosphaera, depending on the character considered. We found that mutation changes the volume of somatic tissue independently of the quantity of germ tissue, so that the interspecific correlation between soma and germ can be attributed to selection. The negative correlation between size and number of germ cells among mutants of V. carteri is also seen among the larger members of the family (Volvox spp.), but not among the smaller members, suggesting a powerful design constraint that may be responsible for the absence of larger forms in the entire group.     

Kinetic studies of electron transfer in the cyt b 5 : metHb system

 The kinetics of methemoglobin reduction by cytochrome b ₅ has been studied by stopped-flow and saturation transfer NMR. A forward rate constant k _f = 2.44×10⁴ M^–1 s^–1 and a reverse rate constant k _b = 540 M^–1s^–1 have been observed at 10 mm, pH 6.20, 25  °C. The ratio k _f/k _b = k _eq = 43.6 is in good agreement with the equilibrium constant calculated from the electrochemical potential between cyt b ₅ and methemoglobin. A bimolecular collisional mechanism is proposed for the electron transfer from cyt b ₅ to methemoglobin based on the kinetic data analysis. The dependence of the rate constants on ionic strengths supports such collisional mechanism. It is also found that the reaction rate strongly depends on the conformations of methemoglobin. Received: 20 February 1996 / Accepted: 4 June 1996     

超低能重离子注入作物育种的原初物理机制

从原子核物理学观点出发,采用理论分析与实验测量并举的方法对超级能（〈２００ｋｅｖ）重离子（Ｚ≥６）注入作物（小麦）种子进行诱变育种的原初物理机制进行了研究,结果表明,无论是注入离子本身的射程,还是次级电子,自由基扩散,高温热穗,级联原子和冲击波等次级作用范围都无法触及表皮下面的胚细胞,但注入离子在麦胚内主要元素（Ｃ,Ｎ,Ｏ,Ｓ,Ｐ,Ｋ,Ｃａ）上激发出的特征Ｘ－射线,在其强度减弱为原来的１０＾－３时     

用多引物PCR分析γ射线引起人外周血淋巴细胞hprt基因突变

正常人外周血用~（６０）Ｃｏ射线分别进行１～８Ｇｙ照射后,在含６－ＴＧ的培养基上克隆和筛选人淋巴细胞ｈｐｒｔ突变细胞。细胞的突变频率与γ射线的照射剂量呈正相关．获得４２个ｈｐｒｔ突变细胞株,用８对ｈｐｒｔ寡核苷酸引物进行多聚酶链反应（ＰＣＲ）从细胞粗提物中分别扩增ｈｐｒｔ各个外显子,分析突变细胞的ｈｐｒｔ基因突变,约６０％（２５／４２）的ｈｐｒｔ基因突变为基因缺失,其中１３个突变是ｈｐｒｔ基因全部缺失,而１２个是部分ｈｐｒｔ基因外显子缺失,约有４０％（１７／４２）的突变无明显的ＰＣＲ扩增变化．同时显示ｈｐｒｔ基因外显子的缺失突变与辐射剂量有关,实验结果提示,此方法有可能用于估计辐射剂量和进行辐射远后效果观察,进而揭示辐射致突的分子机理．