Proteomic and protein interaction network analysis of human T lymphocytes during cell-cycle entry.

Regulating the transition of cells such as T lymphocytes from quiescence (G(0)) into an activated, proliferating state involves initiation of cellular programs resulting in entry into the cell cycle (proliferation), the growth cycle (blastogenesis, cell size) and effector (functional) activation. We show the first proteomic analysis of protein interaction networks activated during entry into the first cell cycle from G(0). We also provide proof of principle that blastogenesis and proliferation programs are separable in primary human T cells. We employed a proteomic profiling method to identify large-scale changes in chromatin/nuclear matrix-bound and unbound proteins in human T lymphocytes during the transition from G(0) into the first cell cycle and mapped them to form functionally annotated, dynamic protein interaction networks. Inhibiting the induction of two proteins involved in two of the most significantly upregulated cellular processes, ribosome biogenesis (eIF6) and hnRNA splicing (SF3B2/SF3B4), showed, respectively, that human T cells can enter the cell cycle without growing in size, or increase in size without entering the cell cycle.

p27Kip1 and p130 cooperate to regulate hematopoietic cell proliferation in vivo.

To investigate the potential functional cooperation between p27Kip1 and p130 in vivo, we generated mice deficient for both p27Kip1 and p130. In p27Kip1-/-; p130-/- mice, the cellularity of the spleens but not the thymi is significantly increased compared with that of their p27Kip1-/- counterparts, affecting the lymphoid, erythroid, and myeloid compartments. In vivo cell proliferation is significantly augmented in the B and T cells, monocytes, macrophages, and erythroid progenitors in the spleens of p27Kip1-/-; p130-/- animals. Immunoprecipitation and immunodepletion studies indicate that p130 can compensate for the absence of p27Kip1 in binding to and repressing CDK2 and is the predominant CDK-inhibitor associated with the inactive CDK2 in the p27Kip1-/- splenocytes. The finding that the p27Kip1-/-; p130-/- splenic B cells are hypersensitive to mitogenic stimulations in vitro lends support to the concept that the hyperproliferation of splenocytes is not a result of the influence of their microenvironment. In summary, our findings provide genetic and molecular evidence to show that p130 is a bona fide cyclin-dependent kinase inhibitor and cooperates with p27Kip1 to regulate hematopoietic cell proliferation in vivo.

Commitment point during G0-->G1 that controls entry into the cell cycle.

Initiation of T-lymphocyte-mediated immune responses involves two cellular processes: entry into the cell cycle (G(0)-->G(1)) for clonal proliferation and coordinated changes in surface and secreted molecules that mediate effector functions. However, a point during G(0)-->G(1) beyond which T cells are committed to enter the cell cycle has not been defined. We define here a G(0)-->G(1) commitment point that occurs 3 to 5 h after CD3 and CD28 stimulation of human CD4 or CD8 T cells. Transition through this point requires cdk6/4-cyclin D, since inhibition with TAT-p16(INK4A) during the first 3 to 5 h prevents cell cycle entry and maintains both naive and memory T cells in G(0). Transition through the G(0)-->G(1) commitment point is also necessary for T cells to increase in size, i.e., to enter the cellular growth cycle. However, transition through this point is not required for the induction of effector functions. These can be initiated while cells are maintained in G(0) with TAT-p16(INK4A). We have termed this quiescent, activated state G(0(A)). Our data provide proof of the principle that entry of T cells into the cell cycle and cellular growth cycles are coupled at the G(0)-->G(1) commitment point but that these processes can be uncoupled from the early expression of molecules of effector functions.

High efficiency protein transduction of quiescent and proliferating primary hematopoietic cells.

Primary hematopoietic cells are relatively refractory to DNA transfection methodologies. This is particularly so when they are quiescent or terminally differentiated and no longer able to divide. However, whole proteins can be introduced into such cells by protein transduction. We have modified the protein transduction domain (PTD) from the HIV-TAT protein used by other investigators. Using green fluorescent protein (GFP) as a reporter, we show that this new sequence allows more efficient transduction of recombinant fusion protein into a variety of hematopoietic cells tested compared with the native HIV TAT domain. This is true for peripheral blood CD34+ cells, dendritic cells, granulocytes, monocytes and lymphocytes all of which are quiescent or terminally differentiated. Furthermore, we were able to transduce myeloblasts from patients with acute myeloid leukemia (AML). In all cell types tested transduction efficiency was almost 100%. Transduction is maximal 15-30 s after addition of PTD or TAT-GFP fusion proteins as tested on quiescent T lymphocytes. This method will allow us to study of the effects of a variety of gene products in cell types that were previously resistant to gene transfection studies.

Epigenetics of human T cells during the G0-->G1 transition.

We investigated functional epigenetic changes that occur in primary human T lymphocytes during entry into the cell cycle and mapped these at the single-nucleosome level by ChIP-chip on tiling arrays for chromosomes 1 and 6. We show that nucleosome loss and flanking active histone marks define active transcriptional start sites (TSSs). Moreover, these signatures are already set at many inducible genes in quiescent cells prior to cell stimulation. In contrast, there is a dearth of the inactive histone mark H3K9me3 at the TSS, and under-representation of H3K9me2 and H3K9me3 defines the body of active genes. At the DNA level, cytosine methylation (meC) is enriched for nucleosomes that remain at the TSS, whereas in general there is a dearth of meC at TSSs. Furthermore, a drop in meC also marks 3' transcription termination, and a peak of meC occurs at stop codons. This mimics the 3' nucleosomal distribution in yeast, which we show does not occur in human T cells.