Tim Hunt

A novel kinase cascade triggered by stress and heat shock that stimulates MAPKAP kinase-2 and phosphorylation of the small heat shock proteins

MAPK-activated protein kinase-2 (MAPKAP kinase-2) is activated in vitro by the p42 and p44 isoforms of MAPK (p42/p44MAPK). In several cell lines, however, MAPKAP kinase-2 is activated by sodium arsenite, heat shock, or osmotic stress and not by agonists that activate p42/p44MAPK. We have identified a MAPK-like enzyme that acts as a MAPKAP kinase-2 reactivating kinase (RK). RK is recognized by an antiserum raised against a Xenopus MAPK (Mpk2), which is most similar to HOG1 from S. cerevisiae. We also identified a RK kinase (RKK) on the basis of its ability to activate either RK or a GST-Mpk2 fusion protein. The RKK, RK, and MAPKAP kinase-2 constitute a new stress-activated signal transduction pathway in vertebrates that is distinct from the classical MAPK cascade.

Cyclin: a protein specified by maternal mRNA in sea urchin eggs that is destroyed at each cleavage division.

Cleavage in embryos of the sea urchin Arbacia punctulata consists of eight very rapid divisions that require continual protein synthesis to sustain them. This synthesis is programmed by stored maternal mRNAs, which code for three or four particularly abundant proteins whose synthesis is barely if at all detectable in the unfertilized egg. One of these proteins is destroyed every time the cells divide. Eggs of the sea urchin Lytechinus pictus and oocytes of the surf clam Spisula solidissima also contain proteins that only start to be made after fertilization and are destroyed at certain points in the cell division cycle. We propose to call these proteins the cyclins.

The cell cycle

‘Dividing cells pass through a regular sequence of cell growth and division, known as the cell cycle’, according to a college textbook of biology published in 1983 [[1][1]], 5 years before the underlying principles of control were first laid bare during 1988, the annus mirabilis of cell cycle

Cyclin is a component of maturation-promoting factor from Xenopus

Highly purified maturation-promoting factor (MPF) from Xenopus eggs contains both cyclin B1 and cyclin B2 as shown by Western blotting and immunoprecipitation using Xenopus anti-B-type cyclin antibodies. Immunoprecipitates with these antibodies display the histone H1 kinase activity characteristic of MPF, for which exogenously added B1 and B2 cyclins are both substrates. Protein kinase activity against cyclin oscillates in maturing oocytes and activated eggs with the same kinetics as p34cdc2 kinase activity. These data indicate that B-type cyclin is the other component of MPF besides p34cdc2.

Phosphorylation of initiation factor eIF-2 and the control of reticulocyte protein synthesis

When rabbit reticulocyte lysates are incubated in the absence of hemin or in the presence of low concentrations of double-stranded RNA, the rate of initiation of protein synthesis is severely reduced after a lag period in which control rates are observed. This reduced initiation rate is due to inhibition of the binding of Methionyl-tRNAf to native 40S ribosomal subunits and is caused by a macromolecular inhibitor which is activated under these conditions. This paper shows that the inhibitors activated in these two situations appear to be different entities, but that in both cases, the inhibitor has an associated protein kinase activity which is highly selective for the small subunit of elF-2, the initiation factor which catalyzes binding of Methionyl-tRNAf to 40S subunits. We present several lines of evidence in support of the hypothesis that the phosphorylation of elF-2 by these kinases is basis of the control of initiation in lysates incubated under these conditions.

[4] Preparation and use of nuclease-treated rabbit reticulocyte lysates for the translation of eukaryotic messenger RNA

Publisher Summary The nuclease-treated rabbit reticulocyte lysate supplemented with heterologous tRNA is the most widely used translation system for eukaryotic mRNAs. This chapter describes the procedures to make the lysate, how to make it dependent on added mRNA, and provide some suggestions for methods of preparing gel-filtered nuclease-treated lysates. The ideal translation system is a reticulocyte lysate from which the endogenous mRNA is removed by fractionation or selective destruction without impairing the intrinsic high activity of the translation machinery. The resulting nuclease-treated lysate has a very low activity, unless eukaryotic mRNAs are added. The reticulocytes are highly specialized cells, and the translation machinery shows little specialization or preference with regard to initiation of protein synthesis on different eukaryotic mRNAs. It is only with respect to the complement of tRNA species that the reticulocyte lysate shows special properties, which may impair its ability to translate heterologous mRNA.

CDK-dependent phosphorylation of BRCA2 as a regulatory mechanism for recombinational repair

Inherited mutations in BRCA2 are associated with a predisposition to early-onset breast cancers. The underlying basis of tumorigenesis is thought to be linked to defects in DNA double-strand break repair by homologous recombination. Here we show that the carboxy-terminal region of BRCA2, which interacts directly with the essential recombination protein RAD51, contains a site (serine 3291; S3291) that is phosphorylated by cyclin-dependent kinases. Phosphorylation of S3291 is low in S phase when recombination is active, but increases as cells progress towards mitosis. This modification blocks C-terminal interactions between BRCA2 and RAD51. However, DNA damage overcomes cell cycle regulation by decreasing S3291 phosphorylation and stimulating interactions with RAD51. These results indicate that S3291 phosphorylation might provide a molecular switch to regulate RAD51 recombination activity, providing new insight into why BRCA2 C-terminal deletions lead to radiation sensitivity and cancer predisposition.

Translation of cyclin mRNA is necessary for extracts of activated Xenopus eggs to enter mitosis

The cyclins are a family of proteins encoded by maternal mRNA. Cyclin polypeptides accumulate during interphase and are destroyed during mitosis at about the time of entry into anaphase. We show here that Xenopus oocytes contain mRNAs encoding two cyclins that are major translation products in a cell-free extract from activated eggs. Cutting these mRNAs with antisense oligonucleotides and endogenous RNAase H blocks entry into mitosis in a cell-free egg extract. The extracts can enter mitosis if either of the cyclin mRNAs is left intact. We conclude that the synthesis of these cyclins is necessary for mitotic cell cycles in cleaving Xenopus embryos.

The cdc2-related protein p40MO15 is the catalytic subunit of a protein kinase that can activate p33cdk2 and p34cdc2.

Activation of the cyclin‐dependent protein kinases p34cdc2 and p33cdk2 requires binding with a cyclin partner and phosphorylation on the first threonine residue in the sequence THEVVTLWYRAPE. We present evidence that this threonine residue, number 160 in p33cdk2, can be specifically phosphorylated by a cdc2‐related protein kinase from Xenopus oocytes called p40MO15. Binding to cyclin A and phosphorylation of this threonine are both required to activate fully the histone H1 kinase activity of p33cdk2. In cell extracts, a portion of p40MO15 is found in a high molecular weight complex that is considerably more active than a lower molecular weight form. Wild‐type MO15 protein expressed in bacteria does not possess kinase activity, but acquires p33cdk2‐T160 kinase activity after incubation with cell extract and ATP. We conclude that p40MO15 corresponds to CAK (cdc2/cdk2 activating kinase) and speculate that, like p33cdk2 and p34cdc2, p40MO15 requires activation by phosphorylation and association with a companion subunit.

Cyclin-dependent kinases and cell-cycle transitions: does one fit all?

Cell-cycle transitions in higher eukaryotes are regulated by different cyclin-dependent kinases (CDKs) and their activating cyclin subunits. Based on pioneering findings that a dominant-negative mutation of CDK1 blocks the cell cycle at G2–M phase, whereas dominant-negative CDK2 inhibits the transition into S phase, a model of cell-cycle control has emerged in which each transition is regulated by a specific subset of CDKs and cyclins. Recent work with gene-targeted mice has led to a revision of this model. We discuss cell-cycle control in light of overlapping and essential functions of the different CDKs and cyclins.