Helga B. Landsverk

Reprogramming fibroblasts to express T-cell functions using cell extracts

We demonstrate here the functional reprogramming of a somatic cell using a nuclear and cytoplasmic extract derived from another somatic cell type. Reprogramming of 293T fibroblasts in an extract from primary human T cells or from a transformed T-cell line is evidenced by nuclear uptake and assembly of transcription factors, induction of activity of a chromatin remodeling complex, histone acetylation, and activation of lymphoid cell–specific genes. Reprogrammed cells express T cell–specific receptors and assemble the interleukin-2 receptor in response to T cell receptor–CD3 (TCR–CD3) complex stimulation. Reprogrammed primary skin fibroblasts also express T cell–specific antigens. After exposure to a neuronal precursor extract, 293T fibroblasts express a neurofilament protein and extend neurite-like outgrowths. In vitro reprogramming of differentiated somatic cells creates possibilities for producing isogenic replacement cells for therapeutic applications.

Reprogrammed gene expression in a somatic cell-free extract

We have developed a somatic cell‐free system that remodels chromatin and activates gene expression in heterologous differentiated nuclei. Extracts of stimulated human T cells elicit chromatin binding of transcriptional activators of the interleukin‐2 (IL‐2) gene, anchoring and activity of a chromatin‐remodeling complex and hyperacetylation of the IL‐2 promoter in purified exogenous resting T‐cell nuclei. The normally repressed IL‐2 gene is transcribed in nuclei from quiescent human T cells and from various non‐T‐cell lines. This demonstrates that somatic cell extracts can be used to reprogram gene expression in differentiated nuclei. In vitro reprogramming may be useful for investigating regulation of gene expression and for producing replacement cells for the treatment of a wide variety of diseases.

AKAP149 is a novel PP1 specifier required to maintain nuclear envelope integrity in G1 phase

Reassembly of the nuclear envelope (NE) at the end of mitosis requires targeting of the B-type lamin protein phosphatase, PP1, to the envelope by A-kinase anchoring protein AKAP149. We show here that NE-associated AKAP149 is a novel PP1-specifying subunit involved in maintaining nuclear architecture through G1 phase. PP1 remains associated with NE-bound AKAP149 during G1 but is released from AKAP149 upon S phase entry, as AKAP149 becomes serine-phosphorylated. NE-associated AKAP149 inhibits PP1 activity towards glycogen phosphorylase but enhances PP1 phosphatase activity towards B-type lamins, indicating that AKAP149 is a B-type lamin specifying subunit of PP1. In vivo dissociation of PP1 from NE-bound AKAP149 in G1-phase nuclei triggers phosphorylation and depolymerization of A- and B-type lamins. The lamins solubilize intranuclearly without affecting the inner nuclear membrane or pore complex distribution. This correlates with the induction of a G1 arrest and, ultimately, apoptosis. We propose that AKAP149-regulated PP1 activity at the NE during G1 is required to maintain nuclear integrity and cell survival.

PNUTS enhances in vitro chromosome decondensation in a PP1-dependent manner.

PP1 (protein phosphatase-1) is a serine/threonine phosphatase involved in mitosis exit and chromosome decondensation. In the present study, we characterize the subcellular and subnuclear localization of PNUTS (PP1 nuclear targeting subunit), a nuclear regulatory subunit of PP1, and report a stimulatory role of PNUTS in the decondensation of prometaphase chromosomes in two in vitro systems. In interphase, PNUTS co-fractionates, together with a fraction of nuclear PP1, primarily with micrococcal nuclease-soluble chromatin. Immunofluorescence analysis shows that PNUTS is targeted to the reforming nuclei in telophase following the assembly of nuclear membranes and concomitantly with chromatin decondensation. In interphase cytosolic extract, ATP-dependent decondensation of prometaphase chromosomes is blocked by PP1-specific inhibitors. In contrast, a recombinant PNUTS(309-691) fragment accelerates chromosome decondensation. This decondensation-promoting activity requires the consensus RVXF PP1-binding motif of PNUTS, whereas a secondary, inhibitory PP1-binding site is dispensable. In a defined buffer system, PNUTS(309-691) also elicits decondensation in an exogenous PP1-dependent manner and, as in the cytosolic extract, a W401A (Thr401-->Ala) mutation that destroys PP1 binding abolishes this activity. The results illustrate an involvement of the PNUTS:PP1 holoenzyme in chromosome decondensation in vitro and argue that PNUTS functions as a PP1-targeting subunit in this process. We hypothesize that targeting of PNUTS to reforming nuclei in telophase may be a part of a signalling event promoting chromatin decondensation as cells re-enter interphase.

The protein phosphatase 1 regulator PNUTS is a new component of the DNA damage response

The function of protein phosphatase 1 nuclear‐targeting subunit (PNUTS)—one of the most abundant nuclear‐targeting subunits of protein phosphatase 1 (PP1c)—remains largely uncharacterized. We show that PNUTS depletion by small interfering RNA activates a G2 checkpoint in unperturbed cells and prolongs G2 checkpoint and Chk1 activation after ionizing‐radiation‐induced DNA damage. Overexpression of PNUTS–enhanced green fluorescent protein (EGFP)—which is rapidly and transiently recruited at DNA damage sites—inhibits G2 arrest. Finally, γH2AX, p53‐binding protein 1, replication protein A and Rad51 foci are present for a prolonged period and clonogenic survival is decreased in PNUTS‐depleted cells after ionizing radiation treatment. We identify the PP1c regulatory subunit PNUTS as a new and integral component of the DNA damage response involved in DNA repair.

Protein phosphatase 1 regulators in DNA damage signaling

In response to DNA damaging agents and endogenous DNA lesions, human cells activate signaling cascades and repair mechanisms to help maintain genomic integrity. Phosphorylation plays a major role in DNA damage signaling, and the role of Ser/Thr kinases, including ATM, ATR, CHK1, CHK2 and DNA-PK, is particularly well documented. While these kinases have taken the center stage in DNA damage signaling until now, a role for Ser/Thr phosphatases is emerging, including Protein Phosphatase 1 (PP1). PP1 substrate specificity is regulated by its binding to a large number of different targeting subunits, and several of these have recently been identified as regulators of DNA damage responses. Here we review recent progress regarding the involvement of PP1 and its binding partners in DNA damage signaling.

DNA-containing extracellular 50-nm particles in the ileal Peyer's patch of sheep.

Follicles of the ileal Peyers patch are sites of B cell proliferation and of diversification of the primary immunoglobulin repertoire in ruminants. We demonstrate here that 50-nm carbonic anhydrase-reactive particles released in the intercellular space in the follicle-associated epithelium of the ileal Peyers patch of lambs contain DNA protected with a detergent-resistant membrane. We named these particles DiCAPs (DNA in carbonic anhydrase particles). DiCAPs can be purified from a suspension collected from ileal Peyers patch follicles by sedimentation in a sucrose gradient. The DiCAP membrane is resistant to several ionic and non-ionic detergents alone, but can be disrupted by a combination of Triton X-100 and proteinase K. Differential nuclease treatment of purified DiCAPs indicates that they contain DNA. Digestion of DiCAP DNA with six-base pair restriction enzymes produces smears, suggesting that individual DiCAPs contain unique sequences. Nonetheless, the size of DiCAP DNA is smaller (approximately 16 kb) than that of lamb genomic DNA. Polymerase chain reaction and sequence analysis of DiCAP DNA reveals the presence of light and heavy chain variable genes as well as housekeeping genes. The data demonstrate the presence of DNA in these extracellular particles, and suggest a role of DiCAPs in transfer of DNA between cells within the ileal Peyers patch. This raises the possibility of a novel form of communication between cells mediated by nucleic acids.

Reprogramming Somatic Nuclei and Cells with Cell Extracts

Publisher Summary This chapter examines procedures for reprogramming somatic nuclei and cells with cell extracts. About 293T human fibroblasts are cultured on glass coverslips. Resuspend the cells in 10 ml ice-cold cell lysis buffer (CLB). It is preferable to use a graduated 15-ml conical tube to estimate the cell volume after sedimentation. Once lysis is achieved in a tube, keep the tube on ice and proceed with all other tubes. Power and duration of sonication vary with each cell type. In order for components from the reprogramming extract to enter 293T cells, the cells must be reversibly permeabilized. Permeabilization is accomplished with the Streptococcus pyogenes toxin, streptolysin O. SLO is a cholesterol-binding toxin that forms large pores in the plasma membrane of mammalian cells. Two additional coverslips should also be used as controls for the absence of SLO. Dilute the SLO stock in ice-cold HBSS to 230 ng/ml. Expression of new proteins can also be monitored at regular intervals after the reprogramming reaction by immunofluorescence or flow cytometry using standard protocols.

Anchoring of protein kinase and phosphatase signaling units

The specificity of action of protein kinases and phosphatases can be achieved by their recruitment into multiprotein complexes at discrete subcellular loci. One class of molecules targeting kinases and phosphatases within single complexes includes A-kinase (PKA) anchoring proteins or AKAPs. Interestingly, AKAPs not only anchor enzymes but may also regulate their activity. Intermolecular interactions within the AKAP complex, or interaction with a substrate, also serve to modulate activity of an associated phosphatase. This communication highlights the role of cytoplasmic and nuclear AKAPs as protein kinase/phosphatase adaptors. Non-AKAP kinase/phosphatase adaptor proteins of the centrosomal complex are also presented.