Defense Mechanisms Research Articles

Insights into the Detoxification of Spruce Monoterpenes by the Eurasian Spruce Bark Beetle.

Plant defence mechanisms, including physical barriers like toughened bark and chemical defences like allelochemicals, are essential for protecting them against pests. Trees allocate non-structural carbohydrates (NSCs) to produce secondary metabolites like monoterpenes, which increase during biotic stress to fend off pests like the Eurasian spruce bark beetle, ESBB (Ips typographus). Despite these defences, the ESBB infests Norway spruce, causing significant ecological damage by exploiting weakened trees and using pheromones for aggregation. However, the mechanism of sensing and resistance towards host allelochemicals in ESBB is poorly understood. We hypothesised that the exposure of ESBB to spruce allelochemicals, especially monoterpenes, leads to an upsurge in the important detoxification genes like P450s, GSTs, UGTs, and transporters, and at the same time, genes responsible for development must be compromised. The current study demonstrates that exposure to monoterpenes like R-limonene and sabiene effectively elevated detoxification enzyme activities. The differential gene expression (DGE) analysis revealed 294 differentially expressed (DE) detoxification genes in response to R-limonene and 426 DE detoxification genes in response to sabiene treatments, with 209 common genes between the treatments. Amongst these, genes from the cytochrome P450 family 4 and 6 genes (CP4 and CP6), esterases, glutathione S-transferases family 1 (GSTT1), UDP-glucuronosyltransferase 2B genes (UDB), and glucose synthesis-related dehydrogenases were highly upregulated. We further validated 19 genes using RT-qPCR. Additionally, we observed similar high expression levels of detoxification genes across different monoterpene treatments, including myrcene and α-pinene, suggesting a conserved detoxification mechanism in ESBB, which demands further investigation. These findings highlight the potential for molecular target-based beetle management strategies targeting these key detoxification genes.

Enhancing Crop Resilience: Insights from Labdane-Related Diterpenoid Phytoalexin Research in Rice (Oryza sativa L.).

Rice (Oryza sativa L.), as one of the most significant food crops worldwide, holds paramount importance for global food security. Throughout its extensive evolutionary journey, rice has evolved a diverse array of defense mechanisms to fend off pest and disease infestations. Notably, labdane-related diterpenoid phytoalexins play a crucial role in aiding rice in its response to both biotic and abiotic stresses. This article provides a comprehensive review of the research advancements pertaining to the chemical structures, biological activities, and biosynthetic pathways, as well as the molecular regulatory mechanisms, underlying labdane-related diterpenoid phytoalexins discovered in rice. This insight into the molecular regulation of labdane-related diterpenoid phytoalexin biosynthesis offers valuable perspectives for future research aimed at improving crop resilience and productivity.

Prospect and Challenges of Litchi Cultivation in Northeast Region of India

The dynamics of pests affecting litchi crops have undergone changes over time, with litchi mites and bugs becoming less economically significant. However, insect pest infestations have emerged as a major constraint, causing substantial economic losses for growers. Litchi trees need to complete their post-harvest vegetative flush in a timely manner to produce a second flush in winter, which will then flower. Litchi fruit is highly perishable and temperature-sensitive, making it difficult to transport to distant markets without adequate cool chain infrastructure. The cumulative effect of biotic and abiotic factors compromises the agricultural value of this cash crop. Investigating natural defense mechanisms in litchi may uncover opportunities to enhance or induce antifungal compounds through defense elicitors. Further research could explore the applicability of these techniques in other countries, although registration issues may arise. Alternatively, other chemicals with similar benefits and lower health risks could be investigated. Additionally, the long-term effects of cincturing on fruit set and tree health warrant further investigation.

Structure and Physiological Significance of IL-17: A Review Article

IL-17 is a pleiotropic cytokine key in lead to the proinflammatory nature within the immune system and thus it has a pronounced effect of inflammation and therefore disease pathogenesis which is particularly relevant in the case of osteoarthritis as well as other immune-mediated inflammatory diseases. While enormous strides have been made regarding its functions, additional studies are required to fill the gaps left over from previous studies and develop novel ways of treating or managing chronic inflammatory conditions on the basis of our advanced understanding of IL-17. IL-17 immune responses are still a mysterious package in acting in defense mechanisms of hosts and at the same trace back to autoimmune disease development due to its biphasic nature— this therefore justifies why an interest for exploring mechanisms by which production is achieved plus effects produced scientifically can be directed towards therapeutic opportunities yet to be fully realized. Such studies will unquestionably provide insights into immune regulation with an optimism for the development of alternative treatment strategies.

Transcriptomic and metabolomic investigations of methyl jasmonate-mediated enhancement of low temperature stress resistance in Cassia obtusifolia L.

Low temperature stress negatively impacts plant growth and development, reducing crop yields by disrupting metabolite production and accumulation. Cassia obtusifolia L., a widely cultivated medicinal plant in subtropical regions, is particularly vulnerable to such stress. Methyl jasmonate (MeJA) regulates plant growth, defense mechanisms, and secondary metabolite production. This study investigated how C. obtusifolia responds to low temperature stress under MeJA treatment using transcriptomic and metabolomic approaches. MeJA treatment upregulated several transcription factor families, including APE/ERF-ERF, WRKY, NAC, and MYB-related, which modulated the plant's response to cold stress. These transcription factors influenced the expression of genes involved in glycolysis, sugar metabolism, and amino acid pathways, contributing to the plant's adaptive responses. Differentially expressed genes were associated with key metabolic processes such as flavonoid biosynthesis, ribosome function, glycolysis/gluconeogenesis, and sugar metabolism. Using H-NMR and LC-MS techniques, we observed that MeJA induced the accumulation of sugars and amino acids in the leaves of C. obtusifolia seedlings under cold stress, while levels of three flavonoid compounds Isoliquiritigenin, Kaempferol-7-O-glucoside, and Phloretin significantly decreased. Enrichment analysis indicated that MeJA modulates the biosynthetic pathways of these compounds in a dose-dependent manner. Integrating metabolomic and transcriptomic data further elucidated alterations in the flavonoid biosynthetic network and other metabolic pathways under low temperature stress. These findings offer insights into the molecular mechanisms underlying flavonoid synthesis and other metabolic adjustments in C. obtusifolia under MeJA treatment.

Adversarial attacks on machine learning-aided visualizations

Abstract Research in ML4VIS investigates how to use machine learning (ML) techniques to generate visualizations, and the field is rapidly growing with high societal impact. However, as with any computational pipeline that employs ML processes, ML4VIS approaches are susceptible to a range of ML-specific adversarial attacks. These attacks can manipulate visualization generations, causing analysts to be tricked and their judgments to be impaired. Due to a lack of synthesis from both visualization and ML perspectives, this security aspect is largely overlooked by the current ML4VIS literature. To bridge this gap, we investigate the potential vulnerabilities of ML-aided visualizations from adversarial attacks using a holistic lens of both visualization and ML perspectives. We first identify the attack surface (i.e., attack entry points) that is unique in ML-aided visualizations. We then exemplify five different adversarial attacks. These examples highlight the range of possible attacks when considering the attack surface and multiple different adversary capabilities. Our results show that adversaries can induce various attacks, such as creating arbitrary and deceptive visualizations, by systematically identifying input attributes that are influential in ML inferences. Based on our observations of the attack surface characteristics and the attack examples, we underline the importance of comprehensive studies of security issues and defense mechanisms as a call of urgency for the ML4VIS community. Graphical abstract

The Battle of LPS Clearance in Host Defense vs. Inflammatory Signaling.

Lipopolysaccharide (LPS) in blood circulation causes endotoxemia and is linked to various disease conditions. Current treatments focus on preventing LPS from interacting with its receptor Toll-like receptor 4 (TLR4) and reducing inflammation. However, our body has a natural defense mechanism: reticuloendothelial cells in the liver rapidly degrade and inactivate much of the circulating LPS within minutes. But this LPS clearance mechanism is not perfect. Excessive LPS that escape this clearance mechanism cause systemic inflammatory damage through TLR4. Despite its importance, the role of reticuloendothelial cells in LPS elimination is not well-studied, especially regarding the specific cells, receptors, and mechanisms involved. This gap hampers the development of effective therapies for endotoxemia and related diseases. This review consolidates the current understanding of LPS clearance, narrates known and explores potential mechanisms, and discusses the relationship between LPS clearance and LPS signaling. It also aims to highlight key insights that can guide the development of strategies to reduce circulating LPS by way of bolstering host defense mechanisms. Ultimately, we seek to provide a foundation for future research that could lead to innovative approaches for enhancing the body's natural ability to clear LPS and thereby lower the risk of endotoxin-related inflammatory diseases, including sepsis.

Game-Changing Antibiotic Solutions for Chronic UTIs in Women

Urinary tract infections (UTIs) are prevalent in primary healthcare settings, with persistent recurrences posing significant challenges. These recurrences necessitate extended antibiotic use, adversely affecting patients' quality of life, mental health, and physical activity. The evolving defense mechanisms of bacteria against the host immune system and antibiotics complicate treatment. This article examines the pathomechanisms of recurrent UTIs, focusing on bacterial defense factors. Understanding these mechanisms is essential for developing innovative treatments, particularly non-antibiotic methods, to reduce antibiotic use and its associated side effects, thereby improving patients' overall well-being. The review synthesizes current knowledge on the pathomechanisms, diagnostics, and treatments for recurrent UTIs, emphasizing the impact on patients' mental and physical health. It highlights innovative, non-antibiotic treatment approaches.

Shaoyao-Gancao Decoction, a famous Chinese medicine formula, protects against APAP-induced liver injury by promoting autophagy/mitophagy

BackgroundAcetaminophen (APAP)-induced hepatotoxicity is a major cause of acute liver failure (ALF), during which autophagy is triggered as a cellular defense mechanism. Shaoyao-Gancao Decoction (SGD), a traditional prescription in Chinese Medicine, is renowned for its therapeutic effects on liver diseases. However, the efficacy and mechanisms of SGD in treating APAP-induced liver injury remain underexplored. PurposeThis study aims to provide robust evidence regarding the protective effects of SGD against APAP overdose in vitro and in vivo, as well as to elucidate its hepatoprotective mechanisms and active components. Study designThe hepatoprotective mechanisms and active components of SGD were investigated through a combination of in vivo and in vitro experiments. MethodsThe protective effects of SGD on APAP-induced liver injury were assessed using a murine model and primary hepatocytes. RNA sequencing and subsequent experimental validations were conducted to uncover the underlying mechanisms of SGD's hepatoprotective actions. Comprehensive chemical profiling of SGD was performed using UHPLC-Q-Exactive Orbitrap HRMS to identify potential active ingredients. Immunohistochemistry, immunofluorescence, quantitative real-time PCR (qPCR), western blotting, enzyme-linked immunosorbent assay (ELISA), and flow cytometry were utilized to investigate the specific cellular changes in liver tissues and hepatocytes influenced by SGD. ResultsSGD was observed to mitigate APAP-induced mitochondrial damage, inflammation, and necrosis by promoting mitochondrial autophagy. The inhibition of autophagy negated the hepatoprotective effects of SGD. Additionally, a detailed characterization of SGD's chemical composition revealed that Licoisoflavone B, Liquiritin, Liquiritin apioside, Licorice saponin G2 and Paeoniflorin Sulfit were potentially critical compounds in the regulation of autophagy and mitophagy. ConclusionOur findings demonstrate that SGD promotes autophagy/mitophagy, which effectively mitigates APAP-induced hepatotoxicity, suggesting SGD's potential as a promising therapeutic agent for APAP-induced liver injury.

Functional Activity of the Antioxidant System of Artemisia Genus Plants in the Republic of Buryatia (Russia) and Its Significance in Plant Adaptation.

Plants are sessile organisms and any changes in environmental factors activate various responses and defense mechanisms. Artemisia plants widely inhabit harsh conditions of arid and semiarid ecosystems. Using two species-a subshrub, Artemisia frigida, and an annual-biennial herb, Artemisia scoparia-the functioning of the antioxidant system of plants in semiarid territories have been examined. The activity of enzymatic antioxidants and the content of non-enzymatic antioxidants in both species as well as the antiradical activity of their extracts have been shown. Although the plants were collected in areas differing in moisture supply, the activity of enzymatic antioxidants and the content of non-enzymatic antioxidants corresponds to their physiological level, within the range of the norm of reaction, in wormwood. Consequently, conditions of differing moisture deficiency do not cause a specific biochemical response at the level of the antioxidant system in the studied species, which confirms their adaptability to these conditions. Meanwhile, A. frigida plants show greater morphological and biochemical plasticity than A. scoparia under changing growth conditions. Both species contain tissue monoterpenoids and sesquiterpenoids, the emission of which provides additional protection against high temperatures and drought. Their composition and contents of phenolic components illustrates the differences in adaptation between perennial and annual plants.

Latitudinal trends in an invasive plant: genetic differentiation, phenotypic plasticity, and the effects of heavy metals and herbivores on growth, defence, and reproductive characteristics

Abstract Background and Aims Invasive species usually demonstrate remarkable adaptability across diverse environments, successfully inhabiting a wide variety of regions. This adaptability often links to genetic differentiation and phenotypic plasticity, leading to latitudinal trends in phenotypic traits. In this study, we collected seeds of invasive plant Phytolacca americana from different latitudes and planted them in homogeneous gardens to investigate the latitudinal variation of P. americana phenotypic traits and to evaluate the effects of herbivory and heavy metals on plant growth, defence, and reproductive characteristics. Methods P. americana seeds from different latitudes were planted in a homogeneous garden. For the experimental treatment, the seeds were divided into four groups: a heavy metal treatment group and its corresponding control group, and a cover treatment group with its corresponding control group. After the fruits matured, their growth, reproduction, and defence indicators were measured. Key Results Significant latitudinal trends were observed in P. americana’s growth and defence characteristics, including changes in branch number, underground biomass, total biomass, and leaf tannin content. Compared to previous field surveys on P. americana, our study found that the latitude trends in growth structure and defence traits were consistent. But the latitudinal trend of reproductive structure is different. Moreover, heavy metals and herbivory substantially influenced the plant’s growth, reproduction, and defence mechanisms, further shaping its latitudinal patterns. Conclusions The observed phenotypic variations in P. americana across latitudes can be largely attributed to the synergistic effects of phenotypic plasticity and genetic variation. At a broader geographical scale, adaptations to heavy metal stress and herbivory pressure among different P. americana populations involve distinct trade-offs related to growth, reproduction, and defence strategies.

The Evolution of the Acylation Mechanism in β-Lactamase and Rapid Protein Dynamics.

β-Lactamases are a class of well-studied enzymes that are known to have existed since billions of years ago, starting as a defense mechanism to stave off competitors and are now enzymes responsible for antibiotic resistance. Using ancestral sequence reconstruction, it is possible to study the crystal structure of a laboratory resurrected 2-3 billion year-old β-lactamase. Comparing the ancestral enzyme to its modern counterpart, a TEM-1 β-lactamase, the structural changes are minor, and it is probable that dynamic effects play an important role in the evolution of function. We used molecular dynamics simulations and employed transition path sampling methods to identify the presence of rate-enhancing dynamics at the femtosecond level in both systems, found that these fast motions are more efficiently coordinated in the modern enzyme, and examined how specific dynamics can pinpoint evolutionary effects that are essential for improving enzymatic catalysis.

Methyl jasmonate enhances rice tolerance to alkaline stress via the auxin pathway

Soil alkalization is a major challenge for global crop production. This study reveals a novel defense mechanism in rice seedlings against alkaline stress, involving methyl jasmonate (MeJA) and auxin pathways. Under alkaline stress (15 mM Na2CO3), rice seedlings exhibited elevated levels of endogenous MeJA and upregulation of JA-responsive genes. Pre-treatment with MeJA (50 µM) significantly improved seedling survival, growth, and mitigated root damage under alkaline stress. This treatment also upregulated genes associated with cell death suppression (OsBI1) and stress tolerance (OsJRL, OsNAC). Notably, MeJA pre-treatment increased auxin (indole-3-acetic acid, IAA) levels in roots, and upregulated genes involved in IAA synthesis (OASA1, OASA2) and auxin signaling (Aux/IAA, ARFs). Blocking auxin transport with N-1-naphthylphthalamic acid intensified root damage under alkaline stress and diminished the protective effect of MeJA. These results highlight the crucial role of MeJA-induced activation of auxin pathway in enhancing rice tolerance to alkaline stress, and provide valuable insights for developing strategies to improve crop resilience in alkaline soils.

Bioactive Compounds Produced by Endophytic Bacteria and Their Plant Hosts-An Insight into the World of Chosen Herbaceous Ruderal Plants in Central Europe.

The natural environment has been significantly impacted by human activity, urbanization, and industrialization, leading to changes in living organisms and their adaptation to harsh conditions. Species, including plants, adapt to these changes by creating mechanisms and modifications that allow them to survive in harsh environments. Also, endophytes, microorganisms that live inside plants, can support plant growth and defense mechanisms in these conditions by synthesizing antimicrobial secondary metabolites. What is more, endophytes produce bioactive metabolites, including alkaloids, amines, and peptides, which play a crucial role in the relationship between endophytes and their host organisms. Endophytes themselves benefit from this by creating a stable environment for their survival and development. The aim of this review is to gain insight into endophytic bioactive metabolites from chosen synanthropic ruderal plants. Industrial activities release pollutants like heavy metals, by-products, and waste, which challenge living organisms and require adaptation. Synanthropic plants, where endophytes are abundant, are particularly valuable for their bioactive compounds, which are used in agriculture and medicine. This review presents, among others, endophytes of herbaceous ruderal plants from central Europe-Chelidonium majus L., Urtica dioica L., Plantago lanceolata L., Matricaria chamomilla L., Equisetum arvense L., Oenothera biennis L., Silybum marianum L., and Mentha piperita L.

MPSD: A Robust Defense Mechanism against Malicious PowerShell Scripts in Windows Systems

This manuscript introduces MPSD (Malicious PowerShell Script Detector), an advanced tool to protect Windows systems from malicious PowerShell commands and scripts commonly used in fileless malware attacks. These scripts are often hidden in Office document macros or downloaded remotely via PowerShell, posing significant threats to corporate networks. A 2018 report revealed that 77% of successful cyberattacks involved fileless malware, with PowerShell being the primary attack method, as highlighted in Red Canary’s 2022 report. To counter these threats, MPSD leverages the Antimalware Scan Interface (AMSI) to intercept and analyze real-time PowerShell scripts, preventing their execution. It further utilizes VirusTotal to filter out malicious scripts. Unlike traditional methods that rely on direct access to scripts, MPSD detects them before execution, addressing the challenge of hidden or obfuscated scripts. Experimental results show that MPSD outperforms well-known antivirus engines, with a low false-negative rate of 1.83%. MPSD is highly effective against evasion techniques like concatenation, encoding, and reordering, making it a robust tool in the cybersecurity landscape.

Oocytes maintain low ROS levels to support the dormancy of primordial follicles.

Primordial follicles (PFs) function as the long-term reserve for female reproduction, remaining dormant in the ovaries and becoming progressively depleted with age. Oxidative stress plays an important role in promoting female reproductive senescence during aging, but the underlying mechanisms remain unclear. Here, we find that low levels of reactive oxygen species (ROS) are essential for sustaining PF dormancy. Compared to growing follicles, oocytes within PFs were shown to be more susceptible to ROS, which accumulates and damages PFs to promote reproductive senescence. Mechanistically, oocytes within PFs were shown to express high levels of the intracellular antioxidant enzyme superoxide dismutase 1 (SOD1), counteracting ROS accumulation. Decreased SOD1 expression, as a result of aging or through the experimental deletion of the Sod1 gene in oocytes, resulted in increased oxidative stress and triggered ferroptosis within PFs. In conclusion, this study identified antioxidant defense mechanisms protecting PFs in mouse ovaries and characterized cell death mechanisms of oxidative stress-induced PF death.

Dermal white adipose tissue: Development and impact on hair follicles, skin defense, and fibrosis.

Dermal white adipose tissue (DWAT) is a distinctive adipose depot located within the lower dermis of the skin. Its significance as an ancillary fat in skin homoeostasis has recently received increased attention. New research has revealed that DWAT responses to skin pathology and physiology changes, impacting skin development, hair cycling, defense mechanisms, and fibrotic conditions. In this review, we explore the developmental process of DWAT and the adipose commitment timing of hypodermal. We explore the development process of DWAT and its pivotal role in regulating the hair cycle. We conclude the antibacterial activity and reversible dedifferentiation of dermal adipocytes in response to skin defense. Furthermore, we underscore the potentially crucial yet underestimated anti-fibrotic functions of DWAT-derived adipokines and adipocyte-myofibroblast transition.

Analysis of fencers’ post-injury adjustment: confirmatory factor analysis

Background and purpose Self-Adjustment is an important factor that every post-injury fencer must consider. Purpose. The aim of this research is to assess the construct validity and reliability of the self-adaptation scale, test the contribution of each aspect and indicator in reflecting the self-adaptation variable, and evaluate the suitability of the theoretical model self-adaptation with empirical data. Self-adaptation is measured through seven aspects, wich include self-regulation, frustration reduction, rational thinking, practical skills, past experiences, reality and goals, and defense mechanisms. Materials and methods The sample in this study was 227 respondents who were fencing athletes who had recovered from injuries. Respondents consisted of 132 men (58.1%) and 95 women (41.9%). The sampling technique employed was purposive sampling, based on specific criteria. To gather the data, a self-adaptation scale was utilized, and the data was subjected to analysis using Structural Equation Modeling (SEM) with second-order CFA via the Lisrel 8.71 software. Results The study’s analysis revealed that injured fencer athletes in Indonesia demonstrate a high level of self-adaptation. The aspects and indicators forming the self-adaptation variable were found to be valid and reliable based on the analysis results. In this context, the training aspect stands out as the most influential factor in reflecting self-adaptation, particularly the ability to practice within the training environment. However, emotional control emerges as the lowest aspect in reflecting self-adaptation, particularly concerning risk perception in their actions. The measurement model of the self-adaptation variable aligns well with the empirical data. To assess the model fit, primary criteria such as Chi-square, RMSEA, RMR, GFI, NFI, NNFI, CFI, IFI, and RFI were employed. Conclusions This research aims to assess the congruence between the theoretical model of self-adaptation variables and the empirical data obtained in the field.

Analysis of Inflammatory and Regulatory Cytokines in the Milk of Dairy Cows with Mastitis: A Comparative Study with Healthy Animals

ABSTRACT Bovine mastitis remains a major problem in the global dairy cattle industry. The acute invasion of udder by pathogens induces innate immune response as the first defence mechanism in subclinical and clinical mastitis. The aim of the study was to determine inflammatory and regulatory cytokines IL-2, IL-4, TGF-β1, IL-17A, beta-defensin 3 and IL-10 and their potential changes in milk of dairy cows with subclinical and clinical mastitis, and to compare the findings with healthy animals. Milk samples from 15 holstein Friesian breed cows were used in the study. Cows were divided into three groups based on their health status (5 healthy, 5 subclinical and 5 clinical animals). All samples were tested using immunohistochemistry to evaluate IL-2, IL-4, IL-10, IL17A, TGF-β1 and β-Def 3 proteins. Expression of all proteins was detected in all milk samples. High expression of IL-2, IL-4, IL17A, TGF-β1 was detected in healthy cows’ milk and in milk of cows with subclinical and clinical mastitis. However, expression of IL-10 and β-Def 3 in milk samples of healthy cows was significantly higher compared to the milk of cows with subclinical and clinical mastitis (p < .001). IL-10 and β-Def 3 can be considered as informative biomarkers in diagnosis of subclinical and clinical mastitis.

An Evaluation of the Security of Bare Machine Computing (BMC) Systems against Cybersecurity Attacks

The Internet has become the primary vehicle for doing almost everything online, and smartphones are needed for almost everyone to live their daily lives. As a result, cybersecurity is a top priority in today’s world. As Internet usage has grown exponentially with billions of users and the proliferation of Internet of Things (IoT) devices, cybersecurity has become a cat-and-mouse game between attackers and defenders. Cyberattacks on systems are commonplace, and defense mechanisms are continually updated to prevent them. Based on a literature review of cybersecurity vulnerabilities, attacks, and preventive measures, we find that cybersecurity problems are rooted in computer system architectures, operating systems, network protocols, design options, heterogeneity, complexity, evolution, open systems, open-source software vulnerabilities, user convenience, ease of Internet access, global users, advertisements, business needs, and the global market. We investigate common cybersecurity vulnerabilities and find that the bare machine computing (BMC) paradigm is a possible solution to address and eliminate their root causes at many levels. We study 22 common cyberattacks, identify their root causes, and investigate preventive mechanisms currently used to address them. We compare conventional and bare machine characteristics and evaluate the BMC paradigm and its applications with respect to these attacks. Our study finds that BMC applications are resilient to most cyberattacks, except for a few physical attacks. We also find that BMC applications have inherent security at all computer and information system levels. Further research is needed to validate the security strengths of BMC systems and applications.