Make it double: identification and characterization of a Tandem-Hirudin from the Asian medicinal leech Hirudinaria manillensis.

Haematophagous leeches express a broad variety of secretory proteins in their salivary glands, among them are hirudins and hirudin-like factors. Here, we describe the identification, molecular and initial functional characterization of Tandem-Hirudin (TH), a novel salivary gland derived factor identified in the Asian medicinal leech, Hirudinaria manillensis. In contrast to the typical structure of hirudins, TH comprises two globular domains arranged in a tandem-like orientation and lacks the elongated C-terminal tail. Similar structures of thrombin inhibitors have so far been identified only in kissing bugs and ticks. Expression of TH was performed in both cell-based and cell-free bacterial systems. A subsequent functional characterization revealed no evidence for a thrombin-inhibitory potency of TH.

Life without blood: Molecular and functional analysis of hirudins and hirudin-like factors of the Asian non-hematophagous leech Whitmania pigra.

BACKGROUND: Several leech species of the genera Hirudo, Hirudinaria, and Whitmania are widely used in traditional Chinese medicine (TCM) for the oral treatment of disorders associated with blood stasis. Among them, the non-hematophagous leech Whitmania pigra expresses a variety of components that have the potential to act on the vertebrate blood coagulation system. OBJECTIVE: Whether the thrombin inhibitor hirudin, probably the most prominent leech-derived anticoagulant, is actually present in Whitmania pigra, is still a matter of debate. To answer that open question was the aim of the study. METHODS: We identified several putative hirudin-encoding sequences in transcriptome data of Whitmania pigra. Upon gene synthesis and molecular cloning the respective recombinant proteins were expressed in Escherichia coli, purified, processed, and eventually functionally characterized for thrombin-inhibitory potencies in coagulation assays. RESULTS: We were successful in the identification and functional characterization of several putative hirudins in Whitmania pigra. Some, but not all, of these factors are indeed thrombin inhibitors. Whitmania pigra hence expresses both hirudins (factors that inhibit thrombin) and hirudin-like factors (that do not or only very weakly inhibit thrombin). Furthermore, we revealed the exon/intron structures of the corresponding genes. Coding sequences of some putative hirudins of Whitmania pigra were present also in transcriptome datasets of Hirudo nipponia, a hematophagous leech that is likewise used in TCM. CONCLUSIONS: Based on both structural and functional data we provide very strong evidence for the expression of hirudins in Whitmania pigra. This is the first description of hirudins in a non-hematophagous leech.

Short tail stories: the hirudin-like factors HLF6 and HLF7 of the Asian medicinal leech, Hirudinaria manillensis.

The leech-derived hirudins and hirudin-like factors (HLFs) share a common molecule structure: a short N-terminus, a central globular domain, and an elongated C-terminal tail. All parts are important for function. HLF6 and HLF7 were identified in the Asian medicinal leech, Hirudinaria manillensis. The genes of both factors encode putative splice variants that differ in length and composition of their respective C-terminal tails. In either case, the tails are considerably shorter compared to hirudins. Here we describe the functional analyses of the natural splice variants and of synthetic variants that comprise an altered N-terminus and/or a modified central globular domain. All natural splice variants of HLF6 and HLF7 display no detectable thrombin-inhibitory potency. In contrast, some synthetic variants effectively inhibit thrombin, even with tails as short as six amino acid residues in length. Our data indicate that size and composition of the C-terminal tail of hirudins and HLFs can vary in a great extent, yet the full protein may still retain the ability to inhibit thrombin.

The hirudin-like factors HLF3 and HLF4-hidden hirudins of European medicinal leeches.

The hirudin-like factors 3 (HLF3) and 4 (HLF4) belong to a new class of leech-derived factors and are present in specimens of the three European medicinal leeches, Hirudo medicinalis, Hirudo verbana, and Hirudo orientalis, respectively. Here we describe the functional analysis of natural and synthetic variants of HLF3 and HLF4. Whereas the natural variants display only very low or no detectable anti-coagulatory activities, modifications within the N-termini in combination with an exchange of the central globular domain have the potency to greatly enhance the inhibitory effects of respective HLF3 and HLF4 variants on blood coagulation. Our results support previous observations on the crucial importance of all parts (both the N- and C-termini as well as the central globular domains) of hirudin and HLF molecules for thrombin inhibition.

Hirudin and Decorsins of the North American Medicinal Leech Macrobdella decora: Gene Structure Reveals Homology to Hirudins and Hirudin-like Factors of Eurasian Medicinal Leeches.

Blood-sucking leeches, some of which are referred to as medicinal leeches, have caught attention not only because of their medical purposes, but also as study organisms to conduct research within fields as diverse as neurobiology, osmoregulation, ecology, and phylogeny. Of particular interest is the question whether hemophagy in leeches is of single origin or evolved independently several times. A key component in the saliva of hematophagous leeches is hirudin, a strong natural inhibitor of thrombin and hence the blood coagulation cascade. Multiple isoforms of hirudin have been described within and among several leech species and genera, often based on sequence data only. The identification of hirudin-like factors (HLFs) illustrated the necessity to underpin such predictions by functional tests. We overexpressed and purified the hirudin of the North American medicinal leech, Macrobdella decora, and proved its thrombin-inhibiting activity. In addition, analysis of the gene structure of both hirudin and some of the decorsins of M. decora clearly indicated conserved exon and intron positions when compared to genes of hirudins and HLFs of Eurasian medicinal leeches. Our data provide evidence for the incorporation of decorsins into the hirudin superfamily and support the concept of a single origin of blood feeding in jawed leeches.

Hirudins of the Asian medicinal leech, Hirudinaria manillensis: same same, but different.

Blood coagulation in vertebrates is a complex mechanism that involves the precisely coordinated and regulated action of a cascade of factors in order to prevent excessive blood loss upon wounding. Any blood sucking ectoparasite, however, has to circumvent this mechanism to ensure the uptake of an adequate blood meal. Inhibitors of blood coagulation in the saliva are hence widespread among these animals. Thrombin as a key factor of blood coagulation is a prominent target of such inhibitors, and hirudin is probably the best known among the thrombin inhibitors. Hirudin was originally described in the genus Hirudo, but occurs in other leech genera like Hirudinaria and Macrobdella as well. Besides several isoforms of hirudin, a new class of putative leech saliva components, the hirudin-like factors (HLFs), was identified in both genera Hirudo and Hirudinaria. Here, we describe the expression, purification, and functional characterization of three HLFs (HLF5, 6, and 8, respectively) and two additional hirudins (HM3 and HM4) of Hirudinaria manillensis. While HLF6 lacked any inhibitory activity on thrombin, HLF5 as well as HLF8 clearly exhibited anticoagulatory properties. The inhibitory activity of HLF5 and HLF8, however, was much lower compared with both HM3 and HM4 of Hirudinaria manillensis as well as the hirudin variants 1 (HV1) and 2 (HV2) of Hirudo medicinalis. Neither an inhibition of trypsin nor a platelet aggregation was caused by HLF8. Our data indicates the presence of two classes (rather than isoforms) of hirudins in Hirudinaria manillensis with markedly different inhibitory activity on human thrombin.

More than just one: multiplicity of Hirudins and Hirudin-like Factors in the Medicinal Leech, Hirudo medicinalis.

Blood-sucking leeches like the medicinal leech, Hirudo medicinalis, have been used for medical purposes since ancient times. During feeding, medicinal leeches transfer a broad range of bioactive substances into the host's wound to prevent premature hemostasis and blood coagulation. Hirudin is probably the best known of these substances. Despite its long history of investigation, recombinant production and clinical use, there still exist conflicting data regarding the primary structure of hirudin. Entirely unclear is the potential biological significance of three different subtypes and many isoforms of hirudins that have been characterized so far. Furthermore, there is only incomplete information on their cDNA sequences and no information at all on gene structures and DNA sequences are available in the databases. Our efforts to fill these gaps revealed the presence of multiple hirudin-encoding genes in the genome of Hirudo medicinalis. We have strong evidence for the expression of all three subtypes of hirudin within individual leeches and for the expression of additional hirudins or hirudin-like factors that may have different biological functions and may be promising candidates for new drugs.

Small bite, large impact-saliva and salivary molecules in the medicinal leech, Hirudo medicinalis.

Blood-sucking leeches have been used for medical purposes in humans for hundreds of years. Accordingly, one of the most prominent species has been named Hirudo medicinalis by Carl Linne in 1758. Feeding on vertebrate blood poses some serious problems to blood-sucking ectoparasites, as they have to penetrate the body surface of the host and to suppress the normal reactions of the host to such injuries (swelling, pain, inflammation) to remain undetected during the feeding period. Furthermore, the parasites have to take measures to inhibit the normal reactions in host tissues to blood vessel damage, namely hemostasis and blood coagulation (platelet aggregation and activation, activation of thrombin and formation of fibrin clots). During evolution, leeches have acquired the ability to control these processes in their hosts by transferring various bioactive substances to the host. These substances are supposedly produced in unicellular salivary gland cells and injected into the wound at the feeding site through tiny salivary ductule openings in the jaws that the leech uses to slice open the host body surface and to cut blood vessels in the depth of the wound. This review summarizes current knowledge about the salivary gland cells and the biological effects of individual saliva components as well as hints to the potential usefulness of some of these compounds for medical purposes.