Turbulence of swarming sperm.

Collective motion of self-sustained swarming flows has recently provided examples of small-scale turbulence arising where viscous effects are dominant. We report the first observation of universal enstrophy cascade in concentrated swarming sperm consistent with a body of evidence built from various independent measurements. We found a well-defined k^{-3} power-law decay of a velocity field power spectrum and relative dispersion of small beads consistent with theoretical predictions in 2D turbulence. Concentrated living sperm displays long-range, correlated whirlpool structures of a size that provides an integral scale of turbulence. We propose a consistent explanation for this quasi-2D turbulence based on self-structured laminated flow forced by steric interactions and alignment, a state of active matter that we call "swarming liquid crystal." We develop scaling arguments consistent with this interpretation.

Protein signatures correspond to survival outcomes of AJCC stage III melanoma patients.

Outcomes for melanoma patients with stage III disease differ widely even within the same subcategory. Molecular signatures that more accurately predict prognosis are needed to stratify patients according to risk. Proteomic analyses were used to identify differentially abundant proteins in extracts of surgically excised samples from patients with stage IIIc melanoma lymph node metastases. Analysis of samples from patients with poor (n = 14, <1 yr) and good (n = 19, >4 yr) survival outcomes identified 84 proteins that were differentially abundant between prognostic groups. Subsequent selected reaction monitoring analysis verified 21 proteins as potential biomarkers for survival. Poor prognosis patients are characterized by increased levels of proteins involved in protein metabolism, nucleic acid metabolism, angiogenesis, deregulation of cellular energetics and methylation processes, and decreased levels of proteins involved in apoptosis and immune response. These proteins are able to classify stage IIIc patients into prognostic subgroups (P < 0.02). This is the first report of potential prognostic markers from stage III melanoma using proteomic analyses. Validation of these protein markers in larger patient cohorts should define protein signatures that enable better stratification of stage III melanoma patients.

Mechanisms of action of fludarabine nucleoside against human Raji lymphoma cells.

Fludarabine (2-FaraAMP) is a purine analog that is effective against chronic lymphocytic leukemia (CLL) and non-Hodgkins lymphoma (NHL). For some cases of CLL, 2-FaraAMP as a single agent can clear the blood of leukemia cells, but leukemia stem cells usually remain protected in sanctuary sites. It is clear that 2-FaraAMP has multiple mechanisms of action that may collectively result in strand breaks in DNA, accumulation of phosphorylated p53 and apoptosis. We have demonstrated using the human Burkitt's lymphoma B-cell line, Raji, that p53, p63 and p73 all accumulate in the nucleus, following treatment of cells with fludarabine nucleoside (2-FaraA). In addition, phosphorylated p53 accumulates in the cytosol and at mitochondria. Using sophisticated methods of proteomic analysis with mass spectrometry, proteins that become differentially abundant after treatment of cells with 2-FaraA have been identified, providing considerable additional information about the cellular responses of B-lymphoid cancers to this purine analog. The levels of proteins involved in the unfolded protein response increase, indicating that endoplasmic reticulum stress is likely to be one mechanism for induction of apoptosis. The levels of a number of proteins found on the outer plasma membrane change on cells treated with 2-FaraA, suggesting that signaling from the B-cell antigen receptor (BCR) is stimulated, resulting in induction of apoptosis through the intrinsic pathway. Increased levels of the cell surface proteins, CD50, CD100 and ECE-1, would promote survival of these cells; the balance between these survival and death responses would determine the fate of the cell.

Fludarabine and cladribine induce changes in surface proteins on human B-lymphoid cell lines involved with apoptosis, cell survival, and antitumor immunity.

Fludarabine and cladribine are purine analogues used to treat hematological malignancies. Alone or in combination with therapeutic antibodies, they are effective in treating patients with chronic lymphocytic leukemia and non-Hodgkin's lymphoma. However, the mechanisms of action of these drugs are not well understood. Plasma membrane proteins perform a variety of essential functions that can be affected by malignancy and perturbed by chemotherapy. Analysis of surface proteins may contribute to an understanding of the mechanisms of action of purine analogues and identify biomarkers for targeted therapy. The surface of human cells is rich in N-linked glycoproteins, enabling use of a hydrazide-coupling technique to enrich for glycoproteins, with iTRAQ labeling for quantitative comparison. A number of plasma membrane proteins on human leukemia and lymphoma cells were affected by treatment with a purine analogue, including decreases in CD22 (an adhesion and signaling molecule) and increases in CD205 (a "damaged cell marker") and CD80 and CD50 (T-cell interaction molecules). Purine analogues may affect B-cell receptor (BCR) signaling and costimulatory molecules, leading to multiple signals for apoptosis and cell clearance. Fludarabine and cladribine induce differential effects, with some cell survival proteins (ECE-1 and CD100) more abundant after fludarabine treatment. Cell surface proteins induced by fludarabine and cladribine may be targets for therapeutic antibodies.

Comprehensive proteomic analysis of the effects of purine analogs on human Raji B-cell lymphoma.

Cladribine (CdA) and fludarabine (FdAMP) are purine analogs that induce apoptosis in chronic lymphocytic leukemia and non-Hodgkin's lymphoma, but the mechanisms are undefined. The effects of CdA and fludarabine nucleoside (FdA) on the cytosolic, mitochondrial, and nuclear proteomes in human Raji lymphoma cells have been determined using two-dimensional fluorescence difference gel electrophoresis (DIGE) and mass spectrometry. Differentially abundant proteins have provided new insights into CdA- and FdA-induced apoptosis. Treatment with these purine analogs induced changes in proteins involved with intermediary metabolism, cell growth, signal transduction, protein metabolism, and regulation of nucleic acids. Differentially abundant mitochondrial 39S ribosomal protein L50, mTERF domain-containing protein 1, Chitinase-3 like 2 protein, and ubiquinone biosynthesis protein COQ9 have been identified in cells undergoing apoptosis. Up-regulation of several stress-associated proteins found in the endoplasmic reticulum (ER) including GRP78, ERp57, and ORP150 suggests that purine analog-induced apoptosis may result from ER stress and unfolded protein response. While mitochondria-dependent apoptosis has been associated with purine analog cytotoxicity, the likely involvement of the ER stress pathway in CdA- and FdA-induced apoptosis has been shown here for the first time.

Membrane proteomics for leukemia classification and drug target identification.

Knowledge of protein expression in the plasma membrane of leukemia cells has contributed to improvements in the detection and treatment of hematological malignancies. Recently engineered antibodies against leukemia surface molecules have improved therapeutic efficacy compared with earlier agents, but there are still side effects. An increased understanding of the surface expression profiles and interactions of membrane proteins on leukemia cells will facilitate the expansion of the role of antibodies in therapy and enable the identification of novel biomarkers for the various stages of leukemogenesis and leukemia progression. Proteomic analysis enables the identification of thousands of proteins in a membrane extract and provides information on their relative abundance, interactions and post-translational modifications. Plasma membrane proteome analysis of leukemia cells can be used to define biomarkers for diagnosis, classification, prognosis and progression monitoring, as well as to predict therapeutic response or resistance. The effects of chemotherapy on the surface proteome and the functional consequences of perturbations to membrane protein networks can provide insights into leukemia cell signaling and survival mechanisms. Surface proteins that are differentially expressed on leukemia cells are prospective targets for the development of engineered antibodies or small-molecule therapeutics. This review focuses on recent discoveries in leukemia membrane proteomics and the potential for future research into leukemia classification and drug target identification.