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Query: UMLS:C0039483 (
giant cell arteritis
)
3,204
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A novel mutation of the N-RAS gene of T-ALL blast cells was detected by a direct sequencing of in vitro amplified exon-1 of the N-RAS gene. Threonine (ACA) was substituted for alanine (
GCA
) at codon 11. This mutation would have been overlooked by conventional probe hybridization techniques. A search for other mutations in N-RAS exon-1 in T-ALL revealed a codon 13 mutation substituting
aspartic acid
(GAT) for glycine (GGT) in one of 18 patients. No mutations at codon 12 were detected.
...
PMID:N-RAS mutations in T-cell acute lymphocytic leukaemia: analysis by direct sequencing detects a novel mutation. 266 Sep
Analysis of 100K-defective temperature-sensitive adenovirus mutants confirmed the multifunctional character of the nonstructural, virus-coded 100K protein. In addition to its function in hexon trimerization (altered in H5ts1), and its possible direct or indirect role in hexon transport to nucleus (mutated in H2ts118), genetic and biochemical evidence was presented that 100K play some critical role in the scaffolding process of adenovirus capsid. This function appeared to be defective in H2ts107 and to map between coordinates 69.0 and 69.9, leftward from the H5ts1 lesion (70-73 map units; Arrand, 1978). This corresponded to the central domain of the 100K protein, between amino acid 300 and 400 from the N end. DNA sequencing of cloned fragments of H2ts107 DNA overlapping the mutation revealed two point mutations on the same codon at nucleotide 25,082 and 25,083 (GAC----
GCA
), corresponding to a nonconservative amino acid change (
aspartic acid
----alanine) at position 324 in the 100K sequence. 100K of adenovirus 2 wild type (WT) was found to bind in significant amounts to novobiocin-affinity column, and to be coeluted with hexon, penton, IIIa, and cellular topoisomerase II activity, by novobiocin- or ATP-Mg2+-containing buffers. H2ts107 100K also bound to novobiocin column, but the elution pattern differed from that of WT, suggesting some alteration in the affinity of the mutated 100K for novobiocin. The same behavior on affinity column as H2ts107 100K was observed for 90K, a cleavage product of the 100K, found in great abundance in H2ts107 at 39.5 degrees and corresponding to the C-terminal moiety of the 100K molecule. This implied that the "novobiocin-binding" domain of the 100K was not confined at its N terminus, and was altered in the H2ts107 mutant.
...
PMID:Hexon trimerization occurring in an assembly-defective, 100K temperature-sensitive mutant of adenovirus 2. 352 Oct 69
The efficiency of translation of the cII gene of bacteriophage lambda is greatly reduced by the cII3059 mutation, a GUU----GAU (Val----
Asp
) change in the second cII codon. Mutations in the third and fourth codons of the cII gene, called ctr mutations, reverse this translation deficiency. Lambda cII3059 ctr-1, which has a
GCA
----ACA (Ala----Thr) change in the fourth cII codon, produces about half the normal level of cII activity in liquid cultures, and lambda cII3059 ctr-2 and lambda cII3059 ctr-3, which have identical CGT----CGC changes in the third codon, produce normal levels of cII activity in liquid culture. Since the cII protein of ctr-3 has the same primary sequence as that of lambda cII3059, the cII- phenotype of lambda cII3059 can be explained entirely by the deficiency of translating cII mRNA. We propose that ctr mutations increase translation efficiency by destabilizing a stable stem structure which can be formed by cII mRNA. The ctr mutations lie in an overlapping regulatory region which contains, in addition to sequence elements that influence the rate of cII translation, a region to which cII protein binds to activate transcription from the PRE promoter. The ctr-1 mutation alters the cII recognition sequence from 5'-T-T-G-C-N6T-T-G-C-3' to 5'-T-T-G-C-N6T-T-G-T-3', but has no effect on PRE activity. Since a C----T change in the first (5'-proximal) T-T-G-C sequence (to yield 5'-T-T-G-T-N6T-T-G-C) greatly lowers cII binding affinity, cII protein must not recognize the two T-T-G-C sequences in an identical manner.
...
PMID:Mutations that alter the DNA binding site for the bacteriophage lambda cII protein and affect the translation efficiency of the cII gene. 624 Dec 64
Mouse immunoglobulin heavy-chain variable region (Ig VH) genes apparently arose from the approximately 600-base-pair-long (approximately 12 tandem repeats of the 48-base-pair-long primordial building block sequence TTC-AGC-AGC-CTG-ACT-GGA-TAT-GAC-CTG-GAG-TGG-ACT-TAC-TGC-
GCA
-AGA) that in the original reading frame specified the amino acid sequence Phe-Ser-Ser-Leu-Thr-Gly-Tyr-
Asp
-Leu-Glu-Trp-Thr-Tyr-Cys-Ala-Arg. The previously identified, shorter prototype building blocks merely represented particular portions of the above primordial sequence. Even today, the direct descendant in toto of this primordial sequence specifies the last one-sixth of each VH coding sequence: the 83rd to 98th amino acid residues. Furthermore, its four truncated derivatives specify the 4th to 14th, 17th to 23rd, 29th to 37th, and 38th to 48th amino acid residues. Accordingly, all three relatively invariant--therefore, conserved--framework regions (FW-1, FW-2, and FW-3) of VHs are specified by recognizable--therefore, conserved--descendants of the primordial sequence.
...
PMID:Identification of the 48-base-long primordial building block sequence of mouse immunoglobulin variable region genes. 680 49
Nature is condemned to play variations of the same theme in evolution, past commitments progressively restricting freedom of choices in evolutionary directions. While each family of genes evolved by the mechanism of gene duplication, this mechanism is extremely inefficient, the usual fate of redundant copies of the ancestral gene being degeneracy. As a result, the euchromatic DNA of higher organisms became a desert in which still-functioning genes are found scattered like oases at an average distance of 35,000 base-pairs of barren stretch between neighbors in the case of mammals. The 20-base-long sequence (AGCTG) (AGCTG) (AGCTG) (GGGTG) can be considered as one of the few ultimate ancestors of all euchromatic DNAs. Long stretches of intergenic spacers are mostly represented by degenerate subfamilies of repeats derived from the above. Certain 30- 50-base-long units of such degenerate subfamilies apparently served as the primordial building block of the ultimate ancestor of each family of genes. For example, the primordial building block of the ancestor for antigen-binding sites (variable regions) of mammalian immunoglobulin heavy chains apparently was TTC-AGC-AGC-CTG-ACT-GGA-TAT GAC-CTG-GAG-TGG-ACT-TAC-TGC-
GCA
-AGA, which is the original reading frame specified in the 16-amino-acid-residues-long sequence Phe-Ser-Ser-Leu-Thr-Gly-Tyr-
Asp
-Leu-Glu-Trp-Thr-Tyr-Cys-Ala-Arg.
...
PMID:Evolution is condemned to rely upon variations of the same theme: the one ancestral sequence for genes and spacers. 682 Jan 35
A 6.4-kb DNA fragment containing the DNA gyrase gyrA and gyrB genes was cloned and sequenced from the quinolone-susceptible Staphylococcus aureus type strain ATCC 12600. An expression plasmid was constructed by inserting the cloned genes into the Escherichia coli-S. aureus shuttle vector pAT19, and deletion plasmids carrying only functional gyrA and gyrB genes were derived from this plasmid. An efficient transformation system for S. aureus RN4220 was established by using these plasmids. Quinolone-resistant mutants of S. aureus RN4220 were isolated by three-step selection with quinolones. The first- and second-step mutants were considered to be transport mutants, and the third-step mutants were divided into five groups with respect to their resistance patterns and transformation results with gyrA and gyrB genes. Sequencing analysis of the resulting mutant gyrase genes showed that they had the following point mutations: group 1, Ser-84 (TCA) to Leu (TTA) in GyrA; group 2, Ser-84 (TCA) to Ala (
GCA
), Ser-85 (TCT) to Pro (CCT), or Glu-88 (GAA) to Lys (AAA) in GyrA; group 3,
Asp
-437 (GAC) to Asn (AAC) in GyrB; group 4, Arg-458 (CGA) to Gln (CAA) in GyrB; and group 5, Ser-85 (TCT) to Pro (CCT) in GyrA and
Asp
-437 (GAC) to Asn (AAC) in GyrB. When the gyrA and/or gyrB mutants were transformed with the wild-type gyrA and/or gyrB plasmids, they became quinolone susceptible, but transformants with the plasmids having the same mutations on the gyrA and/or gyrB genes did not confer susceptibility. These results indicate that mutations in both gyrA and gyrB can be responsible for quinolone resistance in S. aureus.
...
PMID:Quinolone resistance mutations in the DNA gyrase gyrA and gyrB genes of Staphylococcus aureus. 781 Oct 12
DNA sequence analysis of dtxR has shown that the M(r) 25,316 regulatory protein contains a single cysteine residue at position 102. DtxR readily forms inactive disulfide-linked dimers. We have used saturation site-directed mutagenesis of the cysteine codon (TGC) at position 102 in order to determine the role of this residue in metal ion binding. We show that the insertion of amino acids other than cysteine or
aspartic acid
into this position abolishes DtxR function both in vitro and in recombinant Escherichia coli DH5 alpha:lambda RS45toxPO/lacZ. Only those mutant alleles in which the TGC codon for Cys-102 was replaced by either TGT (Cys) or
GCA
(
Asp
) were found to direct the expression of active forms of DtxR that regulate the expression of beta-galactosidase from the toxPO/lacZ transcriptional fusion.
...
PMID:Cysteine-102 is positioned in the metal binding activation site of the Corynebacterium diphtheriae regulatory element DtxR. 837 26
In the present study we investigated the frequency of p16 gene exon 2 mutations in 35 malignant gliomas, using either direct sequencing of the PCR products or cloning into the pCRII vector and sequencing of the cloned PCR products. No mutations were detected during direct sequencing of the PCR products. However, after sequencing of individual clones, we found multiple mutations in 5 tumors involving codons 73(GCC to ACC, Ala to Thr), 76 (GCC to GTC, Ala to Val), 85(GCT to ACT, Ala to Thr), 98(CAC to TAC, His to Tyr), 102 (GCG to GTG, Ala to Val), 106 (GTG to ATG, Val to Met), 107 (CGC to TGC, Arg to Cys), 127 (
GCA
to GTA, Ala to Val), 128 (CGG to TGG, Arg to Trp) and 136 (GGC to GAC, Gly to
Asp
). Mutations were found only in glioblastomas and were either C to T or G to A transitions. Each mutation was detected in a small percentage of tumor cells (1.3-22%) using individual colony sequencing and southern hybridization with mutant oligonucleotides, consistent with the heterogenous cell population of glioblastomas. The presence of p16 gene mutations only in glioblastomas suggests that they are late events in glioma development.
...
PMID:Mutations of the p16 gene in gliomas. 855
Four novel HLA Class II alleles were identified using CANTYPE reverse hybridization assay. The initial unusual SSO hybridization patterns were confirmed by cloning and sequencing analysis. DRB3*0208 allele is identical to DRB3*0202 except for three nucleotide substitutions (GAT-->AGC) changing codon 57 from
Asp
to Ser. This polymorphism has so far been undetected in DRB3 alleles. DRB1*15023 differs from DRB1*15021 by a single silent nucleotide substitution (AAC-->AAT, both encoding for Asn) at codon 33. This polymorphism has not, until now, been identified in DRB alleles. Compared with DQB1*03011, the novel DQB1*03012 contains a single silent nucleotide substitution (
GCA
-->GCG, both encoding for Ala) at codon 38. Finally, DQB1*0614 allele is identical to DQB1*0603 except for a single nucleotide substitution (TAC-->TTC), changing codon 9 from Tyr to Phe. Polymorphisms observed here in the DQB1*03012 and DQB1*0614 alleles are present in several of the known DQB1 alleles. DRB3*0208, DQB1*03012 and DQB1*0614 may have arisen from gene conversion, but the DRB1*15023 most likely was generated by a point mutation event. DQB1*0614 was detected in three related subjects, while each of the other three new alleles has only been detected once.
...
PMID:A novel DRB3 allele (DRB3*0208), a new allelic variant of DRB1*1502 (DRB1*15023) and two new DQB1 (DQB1*03012 and DQB1*0614) alleles. 980 12
Glioblastomas, the most malignant human brain tumors, are characterized by marked aneuploidy, suggesting chromosomal instability which may be caused by a defective mitotic spindle checkpoint. We screened 22 glioblastomas for mutations in the mitotic spindle check-point genes hBUB1, hBUBR1 and hBUB3. DNA sequencing revealed a silent mutation at codon 144 of hBUB1 (CAG-->CAA, Gln-->Gln) in one glioblastoma, a silent mutation at codon 952 of hBUBR1 (GAC-->GAT,
Asp
-->
Asp
) in another glioblastoma, and a silent mutation at codon 388 of the hBUBR1 gene (GCG-->
GCA
, Ala-->Ala) in 8 glioblastomas. We also observed a known polymorphism at hBUBR1 codon 349 (CAA/CGA, Gln/Arg), with an allelic frequency of 0.75 for Gln and 0.25 for Arg, which is similar to that among healthy Caucasian individuals (0.73 vs 0.27). The coding sequence of the hBUB3 gene did not contain any mutation, but in 4 glioblastomas (18%), a C-->T point mutation was detected at position -6 (6 nucleotides upstream of the ATG initiator codon). Analysis of blood DNA of these patients showed identical sequence alterations, indicating that this is a polymorphism. Again, the frequency in glioblastomas was similar to that in healthy Caucasians (15%). We further screened hBUB1 in 18 cases of giant cell glioblastoma, a variant characterized by a predominance of bizarre, multinucleated giant cells. There were no changes, except for a silent mutation at codon 144 in two cases. These results suggest that mutations in these mitotic spindle checkpoint genes do not play a significant role in the causation of chromosomal instability in glioblastomas.
...
PMID:Mutation analysis of hBUB1, hBUBR1 and hBUB3 genes in glioblastomas. 1135
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