Molecular cloning of transcripts that accumulate during the late G1 phase in cultured mouse cells

To identify previously undetected genes that might be involved in later stages of the transition from a quiescent state (G0) to the DNA synthetic phase (S) of murine cells, we set out to isolate cDNA clones derived from mRNAs that appear late in G1 phase in serum-stimulated cells. A lambda-cDNA library was prepared using poly(A)+ RNA from chemically transformed Balb/c 3T3 cells (BP/A31) that had been brought to quiescence and subsequently stimulated for 12 h with serum. From the first screening of approximately 21,000 recombinant phage plaques, about 100 clones were isolated that hybridized to a single-stranded cDNA pool derived from stimulated-cell RNA but not to DNAs made from resting-cell RNA. Eventually, six different clones were identified. The mRNAs from five of these genes increased gradually during the G0 to S transition, in contrast to the "immediate-early" rise of c-myc mRNA or the later rise of thymidine kinase mRNA. These six clones were sequenced and compared to the GenBank database. Clones LG-80, LG-2, and LG-69 are highly homologous to beta-actin, lactate dehydrogenase, and alpha-tubulin. Clones LG-5, LG-61, and LG-74 had no significant homologies to known sequences. A subtractive cDNA library was used to isolate two additional clones, Sub-S1 and Sub-S2; these have homologies to enolase and ribosomal protein L32. Additional studies that examine the function and regulation of these newly identified "late response" genes in the pre-DNA synthesis pathway are in progress.     

Studies on the nature and role of polyadenylated RNA in spore development of Bacillus subtilis

Summary cDNA probes synthesized on poly(A)RNAs isolated from sporulating cells of Bacillus subtilis were used for hybridization studies with RNAs derived from cells at different stages of growth and sporulation. It was shown that these cDNAs hybridized only to RNA from sporulating cells. No hybridization was observed if total RNA isolated from vegetative cells or from stationary phase cells of a zero stage asporogenic mutant was used. The hybridization studies also indicate that at each sporulation stage different poly(A)RNA species are synthesized. Furthermore, the hybridization kinetics have clearly demonstrated the existence of three distinct abundance classes of poly(A)RNA similar to those observed in eukaryotic cells. BamHI endonuclease restriction fragments of B. subtilis DNA that were found to hybridize to labeled poly(A)RNA were ligated to the pHV33 vector and hybrid clones that hybridized efficiently to poly(A)RNA were selected. Among these, three have been found to carry the spoOB gene.These results strongly suggest that the appearance of poly(A)RNA can be correlated to the expression of spore genes.     

Molecular cloning of genes related to aflatoxin biosynthesis by differential screening.

A differential hybridization strategy was used to clone genes associated with aflatoxin biosynthesis. A genomic library, formed between nuclear DNA and the pUC19 plasmid, was screened with three different cDNA probes by the colony hybridization procedure. Nineteen clones were selected; all were positively correlated with and presumably enriched with genes associated with aflatoxin production. Some of these clones were further characterized by using them as probes in Northern (RNA blot) hybridizations. Five clones hybridized strongly with some polyadenylated RNAs formed during the transition to or during idiophase when aflatoxin was produced. However, little or no corresponding hybridization occurred with polyadenylated RNAs formed in early and mid-log growth phase. Two of the clones were further used as probes to hybridize with polyadenylated RNAs formed under aflatoxin-permissive and nonpermissive temperatures. Hybridization occurred with RNA species formed under the permissive temperature only.     

Molecular cloning of genes related to aflatoxin biosynthesis by differential screening.

A differential hybridization strategy was used to clone genes associated with aflatoxin biosynthesis. A genomic library, formed between nuclear DNA and the pUC19 plasmid, was screened with three different cDNA probes by the colony hybridization procedure. Nineteen clones were selected; all were positively correlated with and presumably enriched with genes associated with aflatoxin production. Some of these clones were further characterized by using them as probes in Northern (RNA blot) hybridizations. Five clones hybridized strongly with some polyadenylated RNAs formed during the transition to or during idiophase when aflatoxin was produced. However, little or no corresponding hybridization occurred with polyadenylated RNAs formed in early and mid-log growth phase. Two of the clones were further used as probes to hybridize with polyadenylated RNAs formed under aflatoxin-permissive and nonpermissive temperatures. Hybridization occurred with RNA species formed under the permissive temperature only.     

Amplification and molecular cloning of murine adenosine deaminase gene sequences

A previously isolated mouse Cl-1D derived cell line (B-1/25) overproduces adenosine deaminase (EC 3.5.4.4) by 3200-fold. The present studies were undertaken to determine the molecular basis of this phenomenon. Rabbit reticulocyte lysate and Xenopus oocyte translation studies indicated that the B-1/25 cells also overproduced adenosine deaminase mRNA. Total poly(A+) RNA derived from B-1/25 was used to construct a cDNA library. After prehybridization with excess parental Cl-1D RNA to selectively prehybridize nonamplified sequences, 32P-labeled cDNA probe synthesized from B-1/25 total poly(A+) RNA was used to identify recombinant colonies containing amplified mRNA sequences. Positive clones containing adenosine deaminase gene sequences were identified by blot hybridization analysis and hybridization-selected translation in both rabbit reticulocyte lysate and Xenopus oocyte translation systems. Adenosine deaminase cDNA clones hybridized with three poly(A+) RNA species of 1.5, 1.7, and 5.2 kilobases in length, all of which were overproduced in the B-1/25 cell line. Dot blot hybridization analysis using an adenosine deaminase cDNA clone showed that the elevated adenosine deaminase level in the B-1/25 cells was fully accounted for by an increase in adenosine deaminase gene copy number. The adenosine deaminase cDNA probes and the cell lines with amplified adenosine deaminase genes should prove extremely useful in studying the structure and regulation of the adenosine deaminase gene.     

Identification of cDNA clones for ligninase from Phanerochaete chrysosporium using synthetic oligonucleotide probes

Four cDNA clones for ligninase were isolated from the cDNA library (constructed into the PstI site of E. coli vector pUC9) representing 6 day-old lignin degrading culture of Phanerochaete chrysosporium by the use of three synthetic oligonucleotide probes corresponding to partial amino acid sequences of tryptic peptides of the ligninase. Each of the three probes, 14.1, 14.2 and 25, represents a mixture of 32 12- or 14-base long oligonucleotides. Three cDNA clones hybridized with probe 14.1 but not with probe 25 or 14.2, but one cDNA clone hybridized with all of the three probes. Differential hybridization studies showed that these clones are unique to 6-day poly(A) RNA, but not to 2-day poly(A) RNA.     

Identificaton and characterization of stamen- and tapetum-specific genes from tomato

Summary Differential screening of a tomato cDNA library produced from pre-anthesis stamens resulted in the isolation of 25 cDNA clones that hybridized to probes made from stamen RNA and showed no hybridization to probes made from RNA of vegetative organs. The 25 clones were found to represent 11 noncross-hybridizing classes. The majority of these clones were derived from genes that were single or low copy in the tomato genome. Northern RNA blotting experiments of vegetative and floral organs at several stages of development demonstrated that expression in all 11 classes was confined to floral organs. Of the 11 classes 9 were found to be expressed exclusively in stamens prior to anthesis. Two classes showed expression in immature stamens and in petals, with one of these two additionally being expressed in mature stamens at anthesis. Clones from three of the classes that were expressed exclusively in stamens were used as probes for in situ localization of RNA in floral organs. These experiments demonstrated that expression of the genes corresponding to these clones was confined to the tapetal cells of the anthers. Expression of one of the three genes was found to be limited to a single cell type during the 5–6 day period from late meiosis to immature pollen formation.     

用抑制差减杂交法分离和克隆梭梭幼苗受渗透胁迫诱导相关基因的cDNA片段

以Hoagland溶液培养的梭梭幼苗(H)为对照群体,甘露醇处理的梭梭幼苗(M)为目标群体,进行抑制差减杂交.用经过H cDNA差减的M cDNA构建了一个含有大约400个独立克隆的差减文库;采用差减前的H cDNA和M cDNA以及正向/反向差减杂交后的cDNA为模板标记探针,对随机挑取的100个重组质粒进行差示筛选,获得了21个阳性候选克隆.从这些阳性候选克隆中随机挑取了8个进行Northern blot分析,证实其中3个候选克隆代表了在M中特异表达或表达增强的基因,序列分析和同源性比较表明它们与逆境胁迫有关;而另外5个候选克隆无Northem杂交信号,推测它们为低丰度转录本.     

Molecular cloning of cDNA corresponding to mRNA species whose steady state levels in the thyroid are enhanced by thyrotropin. Homology of one of these sequences with ferritin H

A lambda gt11 cDNA library was constructed using poly(A)+ mRNA from thyrotropin (TSH)-stimulated Fisher rat thyroid (FRTL5) cells. The library was screened for nonthyroglobulin cDNA sequences by differential plaque filter hybridization using single-stranded cDNA probes synthesized from mRNA prepared from quiescent and TSH-stimulated FRTL5 cells. Thyroglobulin cDNA-containing recombinants in the library were avoided by prehybridizing the TSH probe to excess thyroglobulin cDNA. Of 48,000 clones screened, 60 were chosen as representing mRNA species whose abundance was increased in TSH-stimulated versus quiescent cultures. Southern blot analysis of 9 clones confirmed that the TSH-cDNA probe hybridized to a greater extent to the cDNA inserts than did the control probe. cDNA insert sizes varied between 0.3 kilobase (kb) and 1.0 kb. Northern slot blot analysis using as probes the cDNA of four of these clones (FC4, FC26, FC29, and FC43) demonstrated that TSH stimulation of FRTL5 cells increased the steady state levels of the respective mRNA species by 4-12-fold. For all 4 clones, increases in mRNA levels were apparent within approximately 1 h and were maximal after 14-18 h of TSH stimulation. Determination of the partial nucleotide sequence of these 4 clones confirmed that none was thyroglobulin, thyroid peroxidase, or any other gene previously reported to be stimulated by TSH. Three of the clones bore no homology to any known nucleotide sequence, but FC26 was 85% homologous with human ferritin H. Northern blot analysis using the FC26 cDNA insert as a probe confirmed hybridization to an mRNA species of 1 kb, the known size of ferritin H mRNA. In summary, using the technique of differential plaque filter hybridization, we have identified 4 new genes whose mRNA levels are increased by TSH stimulation of thyroid cells. One of these genes is homologous to human ferritin H.     

Molecular cloning and selection of genes regulated in Aspergillus development

Over 350 clones homologous to poly(A)+ RNAs that are significantly more prevalent in conidiating cultures of Aspergillus nidulans than in somatic cells have been selected from a recombinant DNA library formed between nuclear DNA and lambda Charon 4A. The procedure used for this selection involved in situ hybridization to a cDNA probe which had been selectively depleted of sequences represented in somatic cells by complement hybridization. Five of these clones have been characterized further. All but one encoded poly(A)+ RNAs that were at least ten times more prevalent in conidiating cultures than in somatic cells. One clone hybridized to a single, developmentally regulated RNA. The three others were complementary to several RNAs having different molecular weights, each of which was more prevalent in condiating cultures than in vegetative cells. These results and quantitative aspects of the selection procedure suggest that developmentally controlled poly(A)+ RNA coding regions may not be distributed randomly in the Aspergillus genome.