Highly sensitive near-simultaneous assay of multiple "lean meat agent" residues in swine urine using a disposable electrochemiluminescent immunosensors array

Nowadays, β(2)-agonists are abused illegally as "lean meat agents" for food-producing animals, and cause increasing food-safety accidents in some countries. Due to their hazard to the human health, "lean meat agents" are banned in most countries and required to be routinely monitored. We herein report a disposable electrochemiluminescent immunosensors array for near-simultaneous assay of multiple β(2)-agonist residues in swine urine, by using ractopamine and salbutamol as the models. In this investigation, a screen-printed carbon electrodes array was assembled and acted as the substrate of the immunosensors array. Then the immunosensors array was constructed by site-selectively immobilizing the antigens of ractopamine and salbutamol on the working electrodes of array. After the competitive immuno-binding, with the aid of a homemade single-pore-four-throw switch, the electrochemiluminescent signals of the two β(2)-agonists were sequentially detected using a non-array detector. The limits of detection for ractopamine and salbutamol were 8.5 and 17pg/mL, respectively, which were much lower than those of the most previous reports. Compared with other routine methods based on chromatography and ELISA, this method is more suitable for screening of multiple β(2)-agonists in quantities of samples, owing to its merits of low cost, user-friendliness and high throughput, and shows great promise in food safety and agonist surveillance.     

A single conserved basic residue in the potassium channel filter region controls KCNQ1 insensitivity toward scorpion toxins

Although many studies concerning the sensitivity mechanism of scorpion toxin-potassium channel interactions have been reported, few have explored the biochemical insensitivity mechanisms of potassium channel receptors toward natural scorpion toxin peptides, such as the KCNQ1 channel. Here, by sequence alignment analyses of the human KCNQ1 channel and scorpion potassium channel MmKv2, which is completely insensitive to scorpion toxins, we proposed that the insensitivity mechanism of KCNQ1 toward natural scorpion toxins might involve two functional regions, the turret and filter regions. Based on this observation, a series of KCNQ1 mutants were constructed to study molecular mechanisms of the KCNQ1 channel insensitivity toward natural scorpion toxins. Electrophysiological studies of chimera channels showed that the channel filter region controls KCNQ1 insensitivity toward the classical scorpion toxin ChTX. Interestingly, further residue mutant experiments showed that a single basic residue in the filter region determined the insensitivity of KCNQ1 channels toward scorpion toxins. Our present work showed that amino acid residue diversification at common sites controls the sensitivity and insensitivity of potassium channels toward scorpion toxins. The unique insensitivity mechanism of KCNQ1 toward natural scorpion toxins will accelerate the rational design of potent peptide inhibitors toward this channel.     

北方狭口蛙繁殖生态的研究

采用野外定点观察、室内剖检相结合的方法,对北方狭口蛙（Ｋａｌｏｕｔａ ｂｏｒｃａｌｉｓ）繁殖生态进行了研究北方口蛙繁殖期直接与每年的雨季迟早有关,多在大雨过后的傍晚,夜阐及清晨进行繁殖活动,产卵场所为大雨过后形成的临时水坑或流速较缓的沟渠中,产卵场所不受水域大小及水中有无杂草所限,卵分批产出,每批弱卵约２０～３０粒。     

ImKTx1, a new Kv1.3 channel blocker with a unique primary structure

Toxins from the venoms of scorpion, snake, and spider are valuable tools to probe the structure-function relationship of ion channels. In this investigation, a new toxin gene encoding the peptide ImKTx1 was isolated from the venom gland of the scorpion Isometrus maculates by constructing cDNA library method, and the recombinant ImKTx1 peptide was characterized physiologically. The mature peptide of ImKTx1 has 39 amino acid residues including six cross-linked cysteines. The electrophysiological experiments showed that the recombinant ImKTx1 peptide had a pharmacological profile where it inhibited Kv1.3 channel currents with IC(50) of 1.70 n± 1.35 μM, whereas 10 μM rImKTx1 peptide inhibited about 40% Kv1.1 and 42% Kv1.2 channel currents, respectively. In addition, 10 μM rImKTx1 had no effect on the Nav1.2 and Nav1.4 channel currents. Multiple sequence alignments showed that ImKTx1 had no homologous toxin peptide, but it was similar with Ca(2+) channel toxins from scorpion and spider in the arrangement of cysteine residues. These results indicate that ImKTx1 is a new Kv1.3 channel blocker with a unique primary structure. Our results indicate the diversity of K(+) channel toxins from scorpion venoms and also provide a new molecular template targeting Kv1.3 channel.     

SdPI, the first functionally characterized Kunitz-type trypsin inhibitor from scorpion venom

Background

Kunitz-type venom peptides have been isolated from a wide variety of venomous animals. They usually have protease inhibitory activity or potassium channel blocking activity, which by virtue of the effects on predator animals are essential for the survival of venomous animals. However, no Kunitz-type peptides from scorpion venom have been functionally characterized.

Principal Findings

A new Kunitz-type venom peptide gene precursor, SdPI, was cloned and characterized from a venom gland cDNA library of the scorpion Lychas mucronatus. It codes for a signal peptide of 21 residues and a mature peptide of 59 residues. The mature SdPI peptide possesses a unique cysteine framework reticulated by three disulfide bridges, different from all reported Kunitz-type proteins. The recombinant SdPI peptide was functionally expressed. It showed trypsin inhibitory activity with high potency (K_i = 1.6×10⁻⁷ M) and thermostability.

Conclusions

The results illustrated that SdPI is a potent and stable serine protease inhibitor. Further mutagenesis and molecular dynamics simulation revealed that SdPI possesses a serine protease inhibitory active site similar to other Kunitz-type venom peptides. To our knowledge, SdPI is the first functionally characterized Kunitz-type trypsin inhibitor derived from scorpion venom, and it represents a new class of Kunitz-type venom peptides.     

Genomic and Structural Characterization of Kunitz-Type Peptide LmKTT-1a Highlights Diversity and Evolution of Scorpion Potassium Channel Toxins

Background

Recently, a new subfamily of long-chain toxins with a Kunitz-type fold was found in scorpion venom glands. Functionally, these toxins inhibit protease activity and block potassium channels. However, the genomic organization and three-dimensional (3-D) structure of this kind of scorpion toxin has not been reported.

Principal Findings

Here, we characterized the genomic organization and 3-D nuclear magnetic resonance structure of the scorpion Kunitz-type toxin, LmKTT-1a, which has a unique cysteine pattern. The LmKTT-1a gene contained three exons, which were interrupted by two introns located in the mature peptide region. Despite little similarity to other Kunitz-type toxins and a unique pattern of disulfide bridges, LmKTT-1a possessed a conserved Kunitz-type structural fold with one α-helix and two β-sheets. Comparison of the genomic organization, 3-D structure, and functional data of known toxins from the α-KTx, β-KTx, γ-KTx, and κ-KTx subfamily suggested that scorpion Kunitz-type potassium channel toxins might have evolved from a new ancestor that is completely different from the common ancestor of scorpion toxins with a CSα/β fold. Thus, these analyses provide evidence of a new scorpion potassium channel toxin subfamily, which we have named δ-KTx.

Conclusions/Significance

Our results highlight the genomic, structural, and evolutionary diversity of scorpion potassium channel toxins. These findings may accelerate the design and development of diagnostic and therapeutic peptide agents for human potassium channelopathies.