Uncovering kinesin dynamics in neurites with MINFLUX.

Neurons grow neurites of several tens of micrometers in length, necessitating active transport from the cell body by motor proteins. By tracking fluorophores as minimally invasive labels, MINFLUX is able to quantify the motion of those proteins with nanometer/millisecond resolution. Here we study the substeps of a truncated kinesin-1 mutant in primary rat hippocampal neurons, which have so far been mainly observed on polymerized microtubules deposited onto glass coverslips. A gentle fixation protocol largely maintains the structure and surface modifications of the microtubules in the cell. By analyzing the time between the substeps, we identify the ATP-binding state of kinesin-1 and observe the associated rotation of the kinesin-1 head in neurites. We also observed kinesin-1 switching microtubules mid-walk, highlighting the potential of MINFLUX to study the details of active cellular transport.

MINFLUX dissects the unimpeded walking of kinesin-1.

We introduce an interferometric MINFLUX microscope that records protein movements with up to 1.7 nanometer per millisecond spatiotemporal precision. Such precision has previously required attaching disproportionately large beads to the protein, but MINFLUX requires the detection of only about 20 photons from an approximately 1-nanometer-sized fluorophore. Therefore, we were able to study the stepping of the motor protein kinesin-1 on microtubules at up to physiological adenosine-5'-triphosphate (ATP) concentrations. We uncovered rotations of the stalk and the heads of load-free kinesin during stepping and showed that ATP is taken up with a single head bound to the microtubule and that ATP hydrolysis occurs when both heads are bound. Our results show that MINFLUX quantifies (sub)millisecond conformational changes of proteins with minimal disturbance.

A humanized mouse model of liver fibrosis following expansion of transplanted hepatic stellate cells.

Hepatic stellate cells (HSCs) are major contributors to liver fibrosis, as hepatic injuries may cause their transdifferentiation into myofibroblast-like cells capable of producing excessive extracellular matrix proteins. Also, HSCs can modulate engraftment of transplanted hepatocytes and contribute to liver regeneration. Therefore, understanding the biology of human HSCs (hHSCs) is important, but effective methods have not been available to address their fate in vivo. To investigate whether HSCs could engraft and repopulate the liver, we transplanted GFP-transduced immortalized hHSCs into immunodeficient NOD/SCID mice. Biodistribution analysis with radiolabeled hHSCs showed that after intrasplenic injection, the majority of transplanted cells rapidly translocated to the liver. GFP-immunohistochemistry demonstrated that transplanted hHSCs engrafted alongside hepatic sinusoids. Prior permeabilization of the sinusoidal endothelial layer with monocrotaline enhanced engraftment of hHSCs. Transplanted hHSCs remained engrafted without relevant proliferation in the healthy liver. However, after CCl4 or bile duct ligation-induced liver damage, transplanted hHSCs expanded and contributed to extracellular matrix production, formation of bridging cell-septae and cirrhosis-like hepatic pseudolobules. CCl4-induced injury recruited hHSCs mainly to zone 3, whereas after bile duct ligation, hHSCs were mainly in zone 1 of the liver lobule. Transplanted hHSCs neither transdifferentiated into other cell types nor formed tumors in these settings. In conclusion, a humanized mouse model was generated by transplanting hHSCs, which proliferated during hepatic injury and inflammation, and contributed to liver fibrosis. The ability to repopulate the liver with transplanted hHSCs will be particularly significant for mechanistic studies of cell-cell interactions and fibrogenesis within the liver.

TIMP-1 is upregulated, but not essential in hepatic fibrogenesis and carcinogenesis in mice.

Tissue inhibitor of metalloproteinases-1 (TIMP-1) is upregulated during hepatic fibrogenesis and considered to promote fibrosis in the injured liver by inhibition of matrix metalloproteases (MMP) and degradation of extracellular matrix. Moreover, TIMP-1 displays anti-apoptotic properties, in patients with hepatocellular carcinoma (HCC) TIMP-1 serum levels are elevated and high TIMP-1 expression levels in HCC are associated with a poor prognosis. Therefore, TIMP-1 could functionally link fibrogenesis and carcinogenesis in the liver. The aim of our study was to characterize the role of TIMP-1 in hepatic fibrogenesis and carcinogenesis. Experimental hepatic fibrogenesis as well as diethylnitrosamine (DEN) -induced hepatocarcinogenesis were studied in TIMP-1-deficient mice and wild type littermates. Hepatic TIMP-1 expression was upregulated following induction of liver fibrosis by bile duct ligation (BDL) or by carbon tetrachloride (CCl4). Unexpectedly, in comparison to wild type littermates, TIMP-1-deficient mice were not protected from liver fibrosis induced by BDL or CCl4. TIMP-1 expression was significantly higher in HCC nodules than in surrounding liver tissue. However, experimental hepatic carcinogenesis was similar in TIMP-1-deficient mice and wild type littermates following DEN-treatment or combined treatment with DEN and CCl4. Therefore we concluded that TIMP-1 is not essential for hepatic fibrogenesis and carcinogenesis in mice.

Asymmetric dimethylarginine and progression of chronic kidney disease: a one-year follow-up study.

BACKGROUND/AIMS: Asymmetric dimethylarginine (ADMA) is a prognostic factor in patients with chronic kidney disease (CKD). However, the relationships among factors influencing the metabolism of ADMA and the CKD progression are not fully understood. METHODS: Serum ADMA, and variables related to the metabolism of ADMA were measured in 181 non-dialysis patients (CKD stages 3-5) and in 46 controls. Patients were assessed at baseline, and 6 and 12 months after the initiation of the study. RESULTS: Patients had increased baseline ADMA, advanced glycation end products (AGE), and advanced oxidation protein products (AOPP) compared with controls (P<0.001). In a total of 164 patients who completed a one-year study, the estimated GFR (eGFR) declined from 23.5 (17.7-36) mL/min/1.73m(2) to 21 (14.7-31.5) (P=0.018), AGE rose from 1.58 (1.38-1.90) µmol/L to 1.76 (1.52-2.21) (P<0.001), while ADMA, AOPP, tubular function, and proteinuria remained stable. In a multiple regression model (adjusted R(2) = 0.49, P<0.0001), the interaction of relatively higher baseline eGFR, i.e. > 25 mL/min/1.73m(2), with higher ADMA (P=0.02) and higher AOPP (P=0.04) predicted the severest decrease in eGFR per year. Other predictors of progression were higher baseline AGE (P<0.001), proteinuria (P=0.003), hypertension (P=0.01), and higher baseline eGFR (P=0.03). CONCLUSION: Elevated ADMA and markers of oxidative stress were strong predictors of progression in patients with eGFR between 25-40 mL/min/1.73m(2) , i.e. at the borderline of CKD stages 3-4.

Induction of heme oxygenase 1 prevents progression of liver fibrosis in Mdr2 knockout mice.

UNLABELLED: Induction or overexpression of the heme-degrading enzyme, heme oxygenase 1 (HO-1), has been shown to protect mice from liver damage induced by acute inflammation. We have investigated the effects of HO-1 induction in a mouse model of chronic liver inflammation and fibrogenesis with progression to hepatocellular carcinoma (HCC) (Mdr2ko; FVB.129P2-Abcb4(tm1Bor)). HO-1 was induced in vivo by treatment with cobalt protoporphyrin IX, starting at week 5 or 12 of mice lifespan, and continued for 7 weeks. Our results showed that HO-1 induction reduced liver damage and chronic inflammation by regulating immune cell infiltration or proliferation as well as tumor necrosis factor receptor signaling. Fibrosis progression was significantly reduced by HO-1 induction in mice with mild, as well as established, portal and lobular fibrosis. HO-1 induction significantly suppressed hepatic stellate cell activation. During established fibrosis, HO-1 induction was able to revert portal inflammation and fibrosis below levels observed at the start of treatment. Moreover, hepatocellular proliferation and signs of dysplasia were decreased after HO-1 induction. CONCLUSION: Induction of HO-1 interferes with chronic inflammation and fibrogenesis and, in consequence, might delay progression to HCC.

Cell-free plasma DNA during Hemodialysis.

PURPOSE: Cell-free plasma DNA (cfDNA) levels originating predominantly from apoptotic leukocytes were found to rise during hemodialysis (HD) session, and as such are considered a marker of HD membrane biocompatibility. The purpose of our study was to determine the changes of cfDNA during two consecutive high-flux polysulphone HD sessions after a long (HD-L) and short (HD-S) interdialytic interval. METHODS: A total of 17 HD patients were examined. Prior to HD and at 30 and 240 min, cfDNA (using real-time PCR) and leukocyte count were determined. RESULTS: No significant difference was found when comparing pre-HD-S with pre-HD-L cfDNA [4893 (1090-28804) vs. 4589 (691-73796) genomic equivalent/mL]. A significant increase in cfDNA at 240 min was seen in HD-L (p < 0.05) but not in HD-S. Leukocyte count correlated with cfDNA levels before HD-S (r = 0.8; p < 0.01); however, no other correlation was seen between routinely measured biochemical markers and pre-HD cfDNA levels or cfDNA changes during HD. The increase in plasma cfDNA during HD did not correlate with dialysis duration, its efficacy, or ultrafiltration. An association between magnitude of diuresis and cfDNA levels in HD-S was found (r = 0.58; p < 0.05). CONCLUSIONS: The behavior of cfDNA during HD after long and short interdialytic interval is inconsistent and cannot be explained by changes in laboratory and clinical parameters. The observed relationship of plasma cfDNA levels with diuresis deserves further investigation.

Cell-free plasma DNA during peritoneal dialysis and hemodialysis and in patients with chronic kidney disease.

The mechanisms of clearance of circulating plasma DNA are not fully understood, and so we aimed to examine it in patients with impaired renal function compared with healthy individuals. We also assessed the effect of peritoneal dialysis and hemodialysis on circulating plasma cell-free DNA (cfDNA) in our treated patients. Overall, 20 healthy volunteers, 20 patients with chronic kidney disease (CKD), 18 patients undergoing peritoneal dialysis (PD), and 17 patients on hemodialysis (HD; high-flux polysulfone membrane) were examined. Cell-free DNA levels were determined using real-time GADPH gene sequence amplification. The levels of cfDNA in all groups of our patients did not differ significantly from those of healthy volunteers. In HD patients, cfDNA levels were significantly increased compared with those of CKD patients (P < 0.05) and PD-treated patients (P < 0.01). In PD-treated patients, cfDNA was detectable in overnight effluent, with its levels correlating inversely with the duration of PD treatment (r=-0.619, Spearman's coefficient, P= 0.008). Factors contributing to these differences may include changes in the quality and quantity of the cell population of the peritoneum, highlighting the need for additional studies clarifying the dynamics of cfDNA during PD. The plasma levels of cfDNA do not seem to be dramatically altered even in CKD patients or those on PD or HD (as long as they are measured prior to the procedure in the latter two). Our data suggest renal elimination is not the main mechanism of circulating cfDNA clearance.

Citrate anticoagulation control by ionized calcium levels does not prevent hemostasis and complement activation during hemodialysis.

The purpose of this study was to determine whether or not regional citrate anticoagulation (RCA) controlled by ionized calcium (iCa(2+)) would overcome thrombogenicity, prevent hemostasis, and complement activation during hemodialysis (HD). RCA was performed in 10 patients during 10 HD sessions using a polysulfone membrane in an effort to keep iCa(2+) at dialyzer outlet at < or =0.4 mmol/L. Compared to baseline, plasma levels of thrombin-antithrombin III complexes rose significantly at 240 min, and tissue factor and complement C5a component levels at 30 and 240 min of the procedure. Thrombocyte count declined significantly at 30 and 240 min, while activated clotting time (ACT) did not increase significantly, and platelet factor 4 as well as von Willebrand factor levels did not alter significantly. While ACT correlated significantly with some thrombogenicity markers, iCa(2+) did not correlate with ACT, changes in hemostasis, or C5a. We conclude the usually recommended iCa(2+) levels in the HD extracorporeal circuit did not guarantee the complete overcoming of thrombogenicity, prevention of hemostasis, and complement activation.