How VPC Traffic Mirroring Boosts Darktrace Security
09
Mar 2021
Find out how Amazon VPC Traffic Mirroring enhances Darktrace's cloud security. Learn about its impact on advanced threat detection and management.
Darktrace's Cyber AI brings real-time visibility and adaptive, autonomous defense to your AWS cloud security strategy.
The platform continuously learns what normal behavior looks like for every user, device, and workload in your AWS environment. With this deep understanding of usual ‘patterns of life,’ Darktrace can recognize the subtle deviations that point to a threat, from account takeovers to critical misconfigurations.
This bespoke, real-time knowledge of usual activity allows Darktrace to spot the unknown and unpredictable threats that get through policy-based defenses – all without relying on any rules, signatures, or prior assumptions.
With Amazon Virtual Private Cloud (Amazon VPC) Traffic Mirroring, Darktrace’s self-learning AI can seamlessly access granular packet data in AWS cloud environments, helping the platform build a rich understanding of context. AWS’s recent announcement of the extension of VPC Traffic Mirroring to non-Nitro instance types now allows our customers to gain agentless Cyber AI defense across these instances as well.
Expanding VPC traffic mirroring to non-Nitro instances
Amazon VPC Traffic Mirroring replicates the network traffic from EC2 instances within VPCs and allows customers to leverage this traffic for Darktrace’s AI-driven threat detection and investigation. Darktrace’s Cyber AI learns ‘on the job’ what normal activity looks like in customer AWS environments, in part using the real-time visibility provided by VPC Traffic Mirroring. The platform continuously adapts as each customer’s business evolves, a critical feature given the speed and scale of development in the cloud.
Previously, customers could only enable VPC Traffic Mirroring on their Nitro-based EC2 instances. Now, AWS has announced that this seamless access to hundreds of features from network traffic is extended to select non-Nitro instance types, supporting Darktrace’s ability to easily learn the bespoke behavioral patterns of our customers’ Amazon VPCs.
Customers can now enable VPC Traffic Mirroring on additional instances types such as C4, D2, G3, G3s, H1, I3, M4, P2, P3, R4, X1 and X1e that use the Xen-based hypervisor.* This feature is available in all 20 regions where VPC Traffic Mirroring is currently supported.
VPC Traffic Mirroring supports many of Darktrace’s extensive use cases across AWS, which include:
Data exfiltration and destruction: Detects anomalous device connections and user access, as well as unusual resource deletion, modification, and movement;
Critical misconfigurations: Catches open S3 buckets, anomalous permission changes, and unusual activity around compliance-related data and devices;
Compromised credentials: Spots unusual logins, including brute force attempts and unusual login source/time, as well as unusual user behavior, from rule changes to password resets;
Insider threat and admin abuse: Identifies the subtle signs of malicious insiders – including sensitive file access, resource modification, role changes, and adding/deleting users.
Figure 1: Darktrace illuminates activity in AWS
Autonomous investigation and response for AWS cloud environments
The Darktrace Security Module for AWS provides additional visibility across AWS environments via interaction with AWS CloudTrail, allowing for AI-powered monitoring of management and administration activity. With this deep knowledge of how your business operates in the cloud, Darktrace delivers total coverage across all your AWS services, including:
EC2
IAM
S3
VPC
Lambda
Athena
DynamoDB
Route 53
ACM
RDS
The recently announced Version 5 of the Darktrace, which focuses on protecting the cloud and the remote workforce, further augments Darktrace’s coverage of AWS environments. Among many other exciting new features, Version 5 extends the reach of Cyber AI Analyst and Darktrace RESPOND to cloud environments like AWS VPCs.
Cyber AI Analyst augments the work of security teams by autonomously reporting on the full scope of security incidents and reduces triage time by up to 92%. Cyber AI Analyst can now also conduct on-demand investigations into users and devices of interest, ingest third-party alerts to trigger new investigations, and automatically feed AI-generated Incident Reports to any SIEM, SOAR, or downstream ticketing system.
Meanwhile, Darktrace RESPOND brings Autonomous Response to the critical infrastructure which AWS VPCs provide. Darktrace's responses are surgically precise and intelligently maintain normal business operations while stopping emerging threats in real time.**
“Darktrace's innovations are outstanding and have really meshed with our current needs as a security team, from the flexibility of our new cloud-delivered deployment to the extended visibility of the Darktrace Client Sensors.”
– CISO, Real Estate
We have also launched a dedicated user interface for visualization and intuitive analysis of cloud-based threats identified across AWS via the Darktrace Security Module.
Self-Learning AI defense across the enterprise
Darktrace offers AI-driven defense of cloud infrastructure in AWS, as well as across SaaS applications, email, corporate networks, industrial systems, and remote endpoints. Taking a fundamentally unique approach, Darktrace provides the industry’s only self-learning platform that gives complete coverage and visibility across the organization.
This is a critical benefit, as businesses and workforces today are increasingly complex and dynamic. Darktrace can connect the dots between unusual behavior in disparate infrastructure areas and ensure cloud security is not siloed from the monitoring of the rest of the organization.
Darktrace’s adaptive and unified approach allows the solution to detect, investigate, and respond to the full range of threats facing the enterprise – even those unpredictable threats that move across dynamic and diverse environments.
* VPC Traffic Mirroring is not supported on the T2, R3 and I2 instance types and previous generation instances. ** This product is only available in AWS for customers who leverage Darktrace osSensors.
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Inside the SOC
Darktrace cyber analysts are world-class experts in threat intelligence, threat hunting and incident response, and provide 24/7 SOC support to thousands of Darktrace customers around the globe. Inside the SOC is exclusively authored by these experts, providing analysis of cyber incidents and threat trends, based on real-world experience in the field.
Bytesize Security: Insider Threats in Google Workspace
What is an insider threat?
An insider threat is a cyber risk originating from within an organization. These threats can involve actions such as an employee inadvertently clicking on a malicious link (e.g., a phishing email) or an employee with malicious intent conducting data exfiltration for corporate sabotage.
Insiders often exploit their knowledge and access to legitimate corporate tools, presenting a continuous risk to organizations. Defenders must protect their digital estate against threats from both within and outside the organization.
For example, in the summer of 2024, Darktrace / IDENTITY successfully detected a user in a customer environment attempting to steal sensitive data from a trusted Google Workspace service. Despite the use of a legitimate and compliant corporate tool, Darktrace identified anomalies in the user’s behavior that indicated malicious intent.
Attack overview: Insider threat
In June 2024, Darktrace detected unusual activity involving the Software-as-a-Service (SaaS) account of a former employee from a customer organization. This individual, who had recently left the company, was observed downloading a significant amount of data in the form of a “.INDD” file (an Adobe InDesign document typically used to create page layouts [1]) from Google Drive.
While the use of Google Drive and other Google Workspace platforms was not unexpected for this employee, Darktrace identified that the user had logged in from an unfamiliar and suspicious IPv6 address before initiating the download. This anomaly triggered a model alert in Darktrace / IDENTITY, flagging the activity as potentially malicious.
Figure 1: A Model Alert in Darktrace / IDENTITY showing the unusual “.INDD” file being downloaded from Google Workspace.
Following this detection, the customer reached out to Darktrace’s Security Operations Center (SOC) team via the Security Operations Support service for assistance in triaging and investigating the incident further. Darktrace’s SOC team conducted an in-depth investigation, enabling the customer to identify the exact moment of the file download, as well as the contents of the stolen documents. The customer later confirmed that the downloaded files contained sensitive corporate data, including customer details and payment information, likely intended for reuse or sharing with a new employer.
In this particular instance, Darktrace’s Autonomous Response capability was not active, allowing the malicious insider to successfully exfiltrate the files. If Autonomous Response had been enabled, Darktrace would have immediately acted upon detecting the login from an unusual (in this case 100% rare) location by logging out and disabling the SaaS user. This would have provided the customer with the necessary time to review the activity and verify whether the user was authorized to access their SaaS environments.
Conclusion
Insider threats pose a significant challenge for traditional security tools as they involve internal users who are expected to access SaaS platforms. These insiders have preexisting knowledge of the environment, sensitive data, and how to make their activities appear normal, as seen in this case with the use of Google Workspace. This familiarity allows them to avoid having to use more easily detectable intrusion methods like phishing campaigns.
Darktrace’s anomaly detection capabilities, which focus on identifying unusual activity rather than relying on specific rules and signatures, enable it to effectively detect deviations from a user’s expected behavior. For instance, an unusual login from a new location, as in this example, can be flagged even if the subsequent malicious activity appears innocuous due to the use of a trusted application like Google Drive.
Credit to Vivek Rajan (Cyber Analyst) and Ryan Traill (Analyst Content Lead)
Appendices
Darktrace Model Detections
SaaS / Resource::Unusual Download Of Externally Shared Google Workspace File
RansomHub Ransomware: investigación de Darktrace sobre la herramienta más nueva en ShadowSyndicate's Arsenal
What is ShadowSyndicate?
ShadowSyndicate, also known as Infra Storm, is a threat actor reportedly active since July 2022, working with various ransomware groups and affiliates of ransomware programs, such as Quantum, Nokoyawa, and ALPHV. This threat actor employs tools like Cobalt Strike, Sliver, IcedID, and Matanbuchus malware in its attacks. ShadowSyndicate utilizes the same SSH fingerprint (1ca4cbac895fc3bd12417b77fc6ed31d) on many of their servers—85 as of September 2023. At least 52 of these servers have been linked to the Cobalt Strike command and control (C2) framework [1].
What is RansomHub?
First observed following the FBI's takedown of ALPHV/BlackCat in December 2023, RansomHub quickly gained notoriety as a Ransomware-as-a-Service (RaaS) operator. RansomHub capitalized on the law enforcement’s disruption of the LockBit group’s operations in February 2024 to market themselves to potential affiliates who had previously relied on LockBit’s encryptors. RansomHub's success can be largely attributed to their aggressive recruitment on underground forums, leading to the absorption of ex-ALPHV and ex-LockBit affiliates. They were one of the most active ransomware operators in 2024, with approximately 500 victims reported since February, according to their Dedicated Leak Site (DLS) [2].
ShadowSyndicate and RansomHub
External researchers have reported that ShadowSyndicate had as many as seven different ransomware families in their arsenal between July 2022, and September 2023. Now, ShadowSyndicate appears to have added RansomHub’s their formidable stockpile, becoming an affiliate of the RaaS provider [1].
Darktrace’s analysis of ShadowSyndicate across its customer base indicates that the group has been leveraging RansomHub ransomware in multiple attacks in September and October 2024. ShadowSyndicate likely shifted to using RansomHub due to the lucrative rates offered by this RaaS provider, with affiliates receiving up to 90% of the ransom—significantly higher than the general market rate of 70-80% [3].
In many instances where encryption was observed, ransom notes with the naming pattern “README_[a-zA-Z0-9]{6}.txt” were written to affected devices. The content of these ransom notes threatened to release stolen confidential data via RansomHub’s DLS unless a ransom was paid. During these attacks, data exfiltration activity to external endpoints using the SSH protocol was observed. The external endpoints to which the data was transferred were found to coincide with servers previously associated with ShadowSyndicate activity.
Darktrace’s coverage of ShadowSyndicate and RansomHub
Darktrace’s Threat Research team identified high-confidence indicators of compromise (IoCs) linked to the ShadowSyndicate group deploying RansomHub. The investigation revealed four separate incidents impacting Darktrace customers across various sectors, including education, manufacturing, and social services. In the investigated cases, multiple stages of the kill chain were observed, starting with initial internal reconnaissance and leading to eventual file encryption and data exfiltration.
Attack Overview
Internal Reconnaissance
The first observed stage of ShadowSyndicate attacks involved devices making multiple internal connection attempts to other internal devices over key ports, suggesting network scanning and enumeration activity. In this initial phase of the attack, the threat actor gathers critical details and information by scanning the network for open ports that might be potentially exploitable. In cases observed by Darktrace affected devices were typically seen attempting to connect to other internal locations over TCP ports including 22, 445 and 3389.
C2 Communication and Data Exfiltration
In most of the RansomHub cases investigated by Darktrace, unusual connections to endpoints associated with Splashtop, a remote desktop access software, were observed briefly before outbound SSH connections were identified.
Following this, Darktrace detected outbound SSH connections to the external IP address 46.161.27[.]151 using WinSCP, an open-source SSH client for Windows used for secure file transfer. The Cybersecurity and Infrastructure Security Agency (CISA) identified this IP address as malicious and associated it with ShadowSyndicate’s C2 infrastructure [4]. During connections to this IP, multiple gigabytes of data were exfiltrated from customer networks via SSH.
Data exfiltration attempts were consistent across investigated cases; however, the method of egress varied from one attack to another, as one would expect with a RaaS strain being employed by different affiliates. In addition to transfers to ShadowSyndicate’s infrastructure, threat actors were also observed transferring data to the cloud storage and file transfer service, MEGA, via HTTP connections using the ‘rclone’ user agent – a command-line program used to manage files on cloud storage. In another case, data exfiltration activity occurred over port 443, utilizing SSL connections.
Lateral Movement
In investigated incidents, lateral movement activity began shortly after C2 communications were established. In one case, Darktrace identified the unusual use of a new administrative credential which was quickly followed up with multiple suspicious executable file writes to other internal devices on the network.
The filenames for this executable followed the regex naming convention “[a-zA-Z]{6}.exe”, with two observed examples being “bWqQUx.exe” and “sdtMfs.exe”.
Figure 1: Cyber AI Analyst Investigation Process for the SMB Writes of Suspicious Files to Multiple Devices' incident.
Additionally, script files such as “Defeat-Defender2.bat”, “Share.bat”, and “def.bat” were also seen written over SMB, suggesting that threat actors were trying to evade network defenses and detection by antivirus software like Microsoft Defender.
File Encryption
Among the three cases where file encryption activity was observed, file names were changed by adding an extension following the regex format “.[a-zA-Z0-9]{6}”. Ransom notes with a similar naming convention, “README_[a-zA-Z0-9]{6}.txt”, were written to each share. While the content of the ransom notes differed slightly in each case, most contained similar text. Clear indicators in the body of the ransom notes pointed to the use of RansomHub ransomware in these attacks. As is increasingly the case, threat actors employed double extortion tactics, threatening to leak confidential data if the ransom was not paid. Like most ransomware, RansomHub included TOR site links for communication between its "customer service team" and the target.
Figure 2: The graph shows the behavior of a device with encryption activity, using the “SMB Sustained Mimetype Conversion” and “Unusual Activity Events” metrics over three weeks.
Since Darktrace’s Autonomous Response capability was not enabled during the compromise, the ransomware attack succeeded in its objective. However, Darktrace’s Cyber AI Analyst provided comprehensive coverage of the kill chain, enabling the customer to quickly identify affected devices and initiate remediation.
Figure 3: Cyber AI Analyst panel showing the critical incidents of the affected device from one of the cases investigated.
In lieu of Autonomous Response being active on the networks, Darktrace was able to suggest a variety of manual response actions intended to contain the compromise and prevent further malicious activity. Had Autonomous Response been enabled at the time of the attack, these actions would have been quickly applied without any human interaction, potentially halting the ransomware attack earlier in the kill chain.
Figure 4: A list of suggested Autonomous Response actions on the affected devices."
Conclusion
The Darktrace Threat Research team has noted a surge in attacks by the ShadowSyndicate group using RansomHub’s RaaS of late. RaaS has become increasingly popular across the threat landscape due to its ease of access to malware and script execution. As more individual threat actors adopt RaaS, security teams are struggling to defend against the increasing number of opportunistic attacks.
For customers subscribed to Darktrace’s Security Operations Center (SOC) services, the Analyst team promptly investigated detections of the aforementioned unusual and anomalous activities in the initial infection phases. Multiple alerts were raised via Darktrace’s Managed Threat Detection to warn customers of active ransomware incidents. By emphasizing anomaly-based detection and response, Darktrace can effectively identify devices affected by ransomware and take action against emerging activity, minimizing disruption and impact on customer networks.
Credit to Kwa Qing Hong (Senior Cyber Analyst and Deputy Analyst Team Lead, Singapore) and Signe Zahark (Principal Cyber Analyst, Japan)
